KR100547976B1 - Reproducing Apparatus For Optical Recording Media - Google Patents

Abstract

The present invention relates to an apparatus for reproducing an optical recording medium which can increase the recording density.

An apparatus for reproducing an optical recording medium according to the present invention includes: a light collecting means for irradiating a light beam onto an optical recording medium in which a first pit row extending in a straight line and a second pit row wobbling at a predetermined period are alternately arranged in a radial direction; Optical detection means for detecting the amount of light reflected from the optical recording medium in two directions in the track direction to generate first and second signals, and generating third and fourth signals with a delay of the first and second signals for a predetermined time. And signal detecting means for detecting a reproduction information signal based on the first to fourth signals.

According to the present invention, a crosstalk component is periodically detected by irradiating a light beam to follow a centerline of a track to be accessed with respect to an optical recording medium in which linearly extending tracks and wobbled tracks are alternately arranged. By removing the crosstalk component and performing tracking control, accurate information can be reproduced.

Description

Reproducing Apparatus For Optical Recording Media

The present invention relates to an optical recording medium, and more particularly, to an apparatus for reproducing an optical recording medium including a wobbled pit row.

Recently, optical recording media, magneto-optical recording media, etc. have been developed and commercialized as information recording media for recording various kinds of information such as audio and video information. Of these, optical recording media include CD-ROM (CD-Read Only Memory) and DVD-ROM (Digital Versatile Disc-ROM), including CDs (Compact Disc), which have already been generalized, and CD-R ( WORM (Write Once Read Many) type recording media such as CD-Recordable and DVD-R, and rewritable recording media such as CD-Rewritable (CD-RW) and DVD-Random Access Memory (DVD-RAM) It is being spread or developed.

Referring to FIG. 1, a pit row 12 formed in a track on a conventional optical recording medium 10 is shown.

The optical recording medium 10 shown in Fig. 1 stores information in the form of a pit row 12 which constitutes a track which extends from the inner circumference to the outer circumference in the form of a spiral or concentric circle, typically for reproduction. The information recorded in the form of the pit rows 12 is reproduced by detecting the reflected light amount of the light beam irradiated along the track at a constant speed. In this case, the focus for controlling the condensing state of the light beam irradiated to the track and the tracking for controlling the light beam to follow the track are adjusted according to the electrical signal detected from the reflected light incident on the photodetector. In addition, since the reproduction information on the optical recording medium, that is, the position of the track to which the light beam is irradiated, is known by the reproduced information, the optical recording medium can be accessed at random.

On the other hand, since no signal is recorded on the recording disc, a track structure for guiding the information recording tracking state is applied. For example, an optical recording medium such as a CD-R, a DVD-RAM or the like has a track formed of a hill and valley structure. In addition, in order to indicate physical location information and the like for enabling information access random access, the boundary side of the tracks of adjacent mountains and valleys is wobbled at regular intervals. In this case, the pit rows are formed in a straight line along the track reference line on the track of the goal or the track of the hill and the goal.

Recently, as a recording medium for recording a large amount of information such as a moving picture is required, various methods for increasing the recording density of an optical disc have been attempted. For example, in the case of CDs and DVDs, a method of reducing the size of a recording mark or pit or reducing the track pitch between tracks has been attempted. In addition, techniques have been developed that use a short wavelength light source and increase the numerical aperture of the objective lens to reduce the spot diameter of the light beam.

However, since the spot diameter of the light beam is ultimately limited, it is inevitable to reduce the size of the pit or the distance between the tracks. For example, an optical disc for exclusive use of reproduction typically manufactures a disc of a disc on which a desired pit is formed using an exposure apparatus, and inverts and transfers the pit formed on the disc to produce a stamper, and then duplicates the disc using the stamper, that is, a disk substrate. It is produced by molding. Recently, with the development of argon (Ar) lasers and the like, it is possible to form micropits, but since there is no light source corresponding to the micropits in the playback apparatus, as a result, the size and track of the pit are within a range that can be read by the apparatus. Pitch is bound to be limited.

In addition, as blue lasers have been recently developed, it is possible to provide micro light spots, thereby reducing the size of the pit and the track pitch, but in this case, crosstalk between adjacent tracks and inter-symbol interference between front and rear pit A phenomenon such as symbol interference is a problem.

As a result, there is a limit in increasing the recording density in the conventional general pit row (track) structure.

It is therefore an object of the present invention to provide an apparatus for reproducing an optical recording medium having a pit array structure capable of increasing recording density.

In order to achieve the above object, a reproducing apparatus of the optical recording medium of the present invention irradiates a light beam to an optical recording medium in which a first pit row extending in a straight line and a second pit row wobbled in a constant period are alternately arranged radially. A light collecting means for generating the first and second signals by dividing and detecting the amount of light reflected from the optical recording medium in the track direction; And signal detecting means for generating a fourth signal and detecting a reproduction information signal based on the first to fourth signals.

Other objects and advantages of the present invention in addition to the above objects will become apparent from the description of the embodiments 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 illustrates a relationship between a track structure of an optical recording medium and a spot diameter of a light beam irradiated onto the track according to an embodiment of the present invention.

In the optical recording medium 20 shown in FIG. 2, straight tracks 22 and wobbled tracks 24 formed of pit rows are alternately arranged radially. In FIG. 2, when accessing an arbitrary track, such as a straight track 22, it can be seen that the light spots 28A, 28B, 28C irradiated to the straight track 22 also span the adjacent wobbled track 24. . In this case, the crosstalk component by the track 24 adjacent to the inner and outer circumferential sides is inverted in phase and periodically repeated so that the crosstalk component can be easily removed using a signal detected from the reflected light beam.

In detail, when the wobbled track 24 is accessed, the first and second light beams 28A having a time difference of τ of the light beams 28A ', 28B', 28C 'irradiated to the wobbled track 24. ', 28B') is reflected on the photodetector 30 divided in two in the track direction as shown in FIG. Here, τ corresponds to the half period of the wobble period T, and it can be seen that the crosstalk component by the adjacent tracks 22 has a 180 ° phase difference for each half period. In addition, even when the straight track 22 is accessed, the first and second light beams 28A and 28B having a time difference of τ of the light beams 28A, 28B and 28C irradiated to the straight track 22 are provided. The crosstalk component included in the reflected light beam has a 180 ° phase difference as shown in FIG. Accordingly, by delaying the signal detected by the first light beam by τ and calculating it together with the signal detected by the second light beam, the crosstalk component of the frequency band corresponding to the wobble can be detected and removed from the high frequency signal. The tracking error signal for tracking control can also be detected to perform accurate detection and tracking of the reproduced signal.

This makes it possible to set the track pitch relatively smaller than the optical spot diameter of the specific wavelength band, which is advantageous for high density. In addition, by including the pit rows constituting the wobbled track 24, the effect of improving the linear density can also be obtained. In FIG. 2, the wobbled track 24 has a form in which the wobbled portion has a change interval smaller than the pit width and is gently bent. Then, the light beam irradiated onto the straight track 22 or the wobbled track 24 is controlled to follow the track center line 26 of the straight or wobbled shape.

FIG. 5 is a block diagram illustrating an optical recording medium reproducing apparatus according to an exemplary embodiment of the present invention. In the optical recording medium reproducing apparatus illustrated in FIG. ), First and second delays 32 and 34 connected to the output terminal of the photodetector 30, and a first adder amplifier 36 commonly connected to the output terminals of the photodetector 30 and the second delay 34. ), A second add amplifier 38 commonly connected to the output terminals of the photodetector 30 and the first delay 32, and a first common connection to the output terminals of the first and second add amplifiers 36 and 38. A level adjuster for reducing the level of the output signal of the first differential amplifier 40 and the second differential amplifier 42 commonly connected to the differential amplifier 40, the output terminals of the photodetector 30 and the first delay 32. (44), a third adder (46) connected to the output terminal of the photodetector 30, and a third differential amplifier (4) commonly connected to the output terminals of the level adjuster (44) and the third adder amplifier (46). 8).

In the optical recording medium reproducing apparatus shown in FIG. 5, the photodetector 30 is included in an optical pickup (not shown) that generates a beam and irradiates the optical recording medium 20 (not shown). The amount of light reflected by 20 is detected and converted into an electrical signal. In this case, the photodetector 30 has four or two divided photodetection pieces in the track direction so that the distribution state of the beam irradiated to the track can be accurately detected. For convenience, the present invention will be described using the photodetector 30 having a structure divided into two in the track direction. Each of the photodetecting pieces PDa and PDb configured in the two-segment photodetector 30 converts the incident reflected light amount into an electrical signal and is proportional to the reflected light amount of the first and second photodetection signals A and B. Will occur. The first delay 32 delays the first photodetection signal A detected by the photodetection piece PDa on the inner circumferential side by τ. Where τ is T / 2 and T represents the wobble period. Similarly, the second delay 34 delays the second photodetection signal B detected by the photodetection piece PDb on the outer circumference side by τ. The first addition amplifier 36 receives the first photodetection signal A and the second photodetection signal B 'delayed by the second delay 34 to add and amplify. Similarly, the second addition amplifier 38 inputs and amplifies the second photodetection signal B and the first photodetection signal A 'delayed by the first delay 34. The first differential amplifier 40 wobbles by differentially amplifying the sum signal A + B 'output from the first addition amplifier 36 and the sum signal A' + B output from the second addition amplifier 38. The pseudo crosstalk signal X in the frequency band corresponding to the second range is detected. However, since the pseudo crosstalk signal detected by the second addition amplifier 38 has twice the magnitude of the true crosstalk signal, the level adjusting unit 44 reduces the size of the pseudo crosstalk signal X to 1/2. Generates an authentic crosstalk signal. The third addition amplifier 46 adds and amplifies the photodetection signals A and B output from the photodetector 30 to detect the high frequency signal RF. The third differential amplifier 48 inputs a high frequency signal RF output from the third addition amplifier 46 and a true crosstalk signal output from the level adjuster 44 to amplify and differentially amplify the high frequency signal from which the crosstalk component is removed. RF 'is detected and output as a reproduction signal. The second differential amplifier 42 detects the tracking error signal Te by differentially amplifying the second photodetection signal B and the first photodetection signal A ′ delayed by the first delay 32. In addition, the second differential amplifier 42 detects the tracking error signal Te by differentially amplifying the first photodetection signal A and the first photodetection signal B 'delayed by the second delay 34. It may be. In other words, the tracking error signal Te corresponds to the difference signal detected by comparing the photodetection signals detected with opposite phases delayed by τ. The tracking control unit (not shown) adjusts a current signal or a voltage signal supplied to a tracking actuator (not shown) of an optical pickup (not shown) based on the tracking error signal Te, thereby causing the light beam to track the track center line 26. Make sure you can follow.

As described above, according to the optical recording medium according to the present invention, the tracks extending linearly and the wobbled tracks are alternately arranged so that the track pitch can be relatively narrowed with respect to the optical spots of a specific wavelength, thereby greatly improving the recording density. It becomes possible. In addition, the effect of improving the linear density can be obtained by including the pit rows forming the wobbled track. In addition, the optical recording medium driving apparatus according to the present invention removes the crosstalk component by using a crosstalk component periodically detected by irradiating a light beam to follow the centerline of the track to be accessed with respect to the optical recording medium. By performing tracking control, accurate information can be reproduced.

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 schematically shows a track structure formed on a conventional optical recording medium.

2 is a view showing a relationship between a track structure and an optical spot diameter formed on an optical recording medium according to an embodiment of the present invention.

FIG. 3 is a view illustrating a photodetector in which reflected light beams are formed by first and second light beams irradiated to a wobbled track in FIG. 2; FIG.

FIG. 4 is a view of a photodetector in which reflected light beams are formed by first and second light beams irradiated onto a straight track in FIG. 2; FIG.

5 is a diagram showing an apparatus for reproducing an optical recording medium according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

10, 20: optical recording medium 12, 22, 24: pit rows

26: track center line 28A, 28B, 28C: light beam

30: photodetector 32, 34: delay

36, 38, 46: addition amplifier 40, 42, 48: differential amplifier

42: level adjusting unit

Claims (4)

Condensing means for irradiating a light beam to an optical recording medium in which a first pit row extending in a straight line and a second pit row wobbling at a predetermined period are alternately arranged in a radial direction; Light detecting means for detecting the amount of light reflected from the optical recording medium by dividing it in a track direction to generate first and second signals; And optical signal carriers for generating third and fourth signals with a predetermined time delay of the first and second signals, and detecting reproduction information signals based on the first to fourth signals. Playback device. The method of claim 1, And a tracking control means for detecting a tracking error signal by comparing the first signal with a fourth signal or the second signal with a third signal, and performing tracking control of the light beam based on the tracking error signal. An apparatus for reproducing an optical recording medium. The method of claim 2, The tracking control means And the light collecting means controls the light beam to follow the center line of the track. The method of claim 2, The signal detecting means First addition amplifying means for adding and amplifying the first signal and the fourth signal; Second addition amplifying means for adding and amplifying the second signal and the third signal; First differential amplifying means for differentially amplifying output signals of the first and second addition amplifying means; Level adjusting means for detecting a crosstalk component by reducing the magnitude of the output signal of the first differential amplifying means; Third addition amplifying means for adding and amplifying the first and second signals; And second differential amplifying means for differentially amplifying the output signal of said third adding amplifying means and said crosstalk component to generate said reproducing information signal.