KR100373527B1 - Apparatus and Method of Information Reproduction in Optical medium - Google Patents

Abstract

The present invention relates to an information reproducing method of an optical recording medium capable of removing noise affecting a high frequency signal.

The information reproducing method of the optical recording medium of the present invention comprises the steps of detecting a high frequency signal from a main spot, detecting a wobbling signal from a sub spot, synchronizing a wobble signal with a delayed high frequency signal for a predetermined time; And subtracting the wobbling signal from the high frequency signal to remove noise mixed in the high frequency signal.

According to the present invention, it is possible to remove the wobbling signal, that is, the noise, mixed into the high frequency signal. Therefore, the amplitude of the wobble can be made large, and signal degradation due to reproduction and repetition of recording can be prevented.

Description

Apparatus and Method of Information Reproduction in Optical medium

The present invention relates to a method and apparatus for reproducing information of an optical record carrier, and more particularly, to a method and apparatus for reproducing information of an optical record carrier capable of removing noise affecting a high frequency signal.

Recently, optical recording media and magneto-optical recording media have been developed and commercialized as recording media for recording various kinds of information such as video and audio information. Among them, optical recording media include CD-ROMs (Read Only Memory) and DVD (Digital Versatile Disk) -ROMs, including compact discs (CDs) that have already been generalized, and CD-Rs (Recordable) and DVD-Rs. WORM (Write Once Read Memory) type discs, such as, and rewritable discs such as CD-RW (Rewritable) and DVD-RAM (Random Access Memory), are being spread or developed.

In a conventional recordable disc, identification (hereinafter referred to as " ID ") information including address (location) information or the like is recorded in advance so that information can be recorded in a desired position. In fact, an optical disc such as a CD-R has a mountain signal track 10 and a valley signal track 12, as shown in FIG. 1, and in accordance with a carrier signal in which ID information including address information and the like is frequency modulated. The signal track 12 is wobbling. The address information can be read by the wobbling signal picked up from the signal track 12 of the wobbled goal as described above, and the information can be recorded at a desired position on the disc based on this address information. However, in this type of disc, since information is recorded only in the signal track 12 of the goal, the recording capacity of the information is limited.

A disc (for example, a DVD-RAM) as shown in FIG. 2 is known as a disc on which information can be recorded on both mountain and valley signal tracks. This disc includes recording fields consisting of signal tracks 10 and 12 of mountain and valley wobbled in phase with header fields in which ID information including address information and the like is recorded in the form of prepit columns 14. Doing. In this type of disc, since information cannot be recorded in the header field consisting of the prepit columns 14, the recording capacity is limited.

In order to overcome this disadvantage and maximize the amount of information to be recorded in both the mountain and valley signal tracks 10 and 12, a recording method as shown in FIG. 3 has been proposed.

Referring to Fig. 3, there is shown a conventional optical disk in which signal tracks 20 and 22 of mountain and valley are formed. Each of the mountain and valley signal tracks 20 and 22 alternates between an in-phase wobbling region 24A in which both sides are wobbed in phase and a two-phase wobbling region 24B in which the two sides are in phase different from each other. The in-phase wobbling region 24A and the out-of-phase wobbling region 24B are alternated in the width direction of the signal tracks 20 and 22. The in-phase wobbling area 24A indicated by hatching is an area in which ID information including address information and the like is preformatted on both sides, and both sides are wobbled according to a carrier signal on which ID information is frequency-modulated. Since the in-phase wobbling regions 24A are alternately arranged with the two-phase wobbling regions 24B in the advancing and width directions of the signal tracks 20 and 22, both sides of the two-phase wobbling regions 24B Wobbled to a different phase. That is, the out-of-phase wobbling regions 24B include a region that is wobbed in two phases or a region that is partially wobbed in two phases as it is alternately arranged with the in-phase wobbling region 24A. As a result, address information is obtained from the wobbling signal on the in-phase wobbled region 24A. For example, when the in-phase wobbling area 24A and the out-of-phase wobbling area 24B are used as one information recording unit (i.e., a frame) as shown in FIG. 3, the front of the in-phase wobbling area 24B is shown. Alternatively, address information can be read from the in-phase wobbling area 24A located later, and user information can be recorded in the information recording unit based on the read address information. Therefore, information is recorded on both the mountain signal track 20 and the valley signal track 22 in the recording medium in this manner, and further, all the recordable areas are utilized.

In order to reproduce the information recorded in this manner, the light spots 30, 32, 34 are moved along the signal tracks 20, 22 of the mountain and valley as shown in FIG. 4, and the light spots 30, 32 and 34 detect a radio frequency (RF) and a wobbling signal (W). The light spots 30, 32, 34 are divided into a main spot 30 and a sub spot 32, 34. The signals detected from the sub spots 32 and 34 are used to generate a tracking error signal together with the detection signal of the main spot 30. Data stored in the optical disc is reproduced through the high frequency signal RF detected from the main spot 30, and identification information, position information, rotational speed of the optical disc and the recording / reproducing clock are made through the wobbling signal W. A signal or the like is detected. For this purpose, the main spot 30 is divided into four light detection pieces Pa to Pd. These four photodetecting pieces Pa to Pd are correspondingly positioned two by two based on the advancing direction of the signal track. That is, the first and fourth photodetector pieces Pa and Pd are positioned at one side of the signal track, and the second and third photodetector pieces Pb and Pc are the first and fourth photodetector pieces Pa and Pd. On the opposite side). The wobbling signal W and the high frequency signal RF are detected from the first to fourth light detecting pieces Pa to Pd through the calculation process of Equations 1 and 2.

RF = Pa + Pb + Pc + Pd

W = (Pa + Pd)-(Pb + Pc)

The high frequency signal RF and the wobbling signal W detected by Equations 1 and 2 are shown in FIGS. 5A to 5D.

Referring to FIG. 5A, a high frequency signal 36 and a wobbling signal 38 in an area where no signal is recorded are shown. When the wobble signal 38 is enlarged in the in-phase wobble region 24A, it can be seen that the wobble signal 42 is detected in all sections of the in-phase wobble region 24A. Accordingly, the wobbling signal 42 is not mixed with the high frequency signal 40 in the in-phase wobbling region 24A. This can be seen by comparing the portion 42 in which the wobbling signal 38 is enlarged with the portion 40 in which the high frequency signal 36 is enlarged. 5B shows the high frequency signal 50 and the wobbling signal 38 in the region where the signal is recorded. When the high frequency signal 50 is enlarged in the in-phase wobbling region 24A, it can be seen that the high frequency signal 54 is constant in all sections of the in-phase wobbling region 24A. That is, the wobbling signal 42 is not mixed in the high frequency signal 54 in the in-phase wobbling region 24A. However, when the wobbling signal 38 is enlarged in the two-phase wobbling area 24B, the wobble signal 48 is not detected in some sections as shown in FIG. 5C. As such, it can be seen that noise 44a, 44b, and 44c, that is, a wobbling signal, are mixed in the high frequency signal 46 in a section where the wobble signal 48 is not detected. This can be seen by comparing the portion 48 in which the wobbling signal 38 is enlarged with the portion 46 in which the high frequency signal 36 is enlarged. 5D shows the high frequency signal 50 and the wobbling signal 38 in the region where the signal is recorded. When the high frequency signal 50 is enlarged in the out of phase wobbling region 24B, it is understood that noise 62a and 62b are mixed in the high frequency signal 58 in the section where the wobbling signal 60 does not appear. . Such noises 62a and 62b become more mixed as the wobble amplitude increases. Therefore, the amplitude of the wobble cannot be set to a predetermined value or more due to the noises 62a and 62b appearing in the two-phase wobble region 24B. When the wobble amplitude is set to be smaller than or equal to this, a signal degradation phenomenon occurs due to reproduction and repetition of recording.

6A to 6D are diagrams showing high frequency signals which are detected differently according to the size of the recording mark.

6A is a high frequency signal RF when 3T recording marks are continuously recorded on the optical recording medium, and FIG. 6B is a high frequency signal when 5T recording marks are continuously recorded on the optical recording medium. RF). 6C is a high frequency signal RF when 8T recording marks are continuously recorded on the optical recording medium, and FIG. 6D is a high frequency signal when 11T recording marks are continuously recorded on the optical recording medium. Signal RF.

6A to 6D, it can be seen that the high frequency signal RF is differently represented by the size of the recording marks and the interval of the track pitch (0.37 μm, 0.325 μm, 0.284 μm). In practice, recording marks of various sizes are continuously recorded on the optical recording medium. Therefore, the high frequency signals RF, which appear in various ways depending on the size of the recording marks, are mixed with each other and act as noise in the out of phase wobbling area 24B.

Accordingly, an object of the present invention is to provide a method and apparatus for reproducing information of an optical recording medium which can eliminate noise affecting a high frequency signal.

1 is a diagram schematically showing a signal track structure of a CD-R disc.

2 is a diagram schematically showing a signal track structure of a DVD-RAM disc.

3 is a diagram schematically showing a signal track structure of an optical disc capable of recording information on signal tracks of mountains and valleys.

4 is a diagram showing a method of reproducing information recorded on an optical disc.

5A and 5C are diagrams showing a high frequency signal and a wobbling signal reproduced in two-phase and in-phase wobbling regions of an optical disc on which information is not recorded.

5B and 5D are diagrams showing high frequency signals and wobbling signals reproduced in two-phase and in-phase wobbling regions of an optical disc on which information is recorded;

6A to 6D are diagrams showing high frequency signals detected differently from each other according to the size of a recording mark.

7 is a diagram showing a method of reproducing information stored in an optical disc according to an embodiment of the present invention.

8 shows track pitches of in-phase and out-of-phase wobbling regions of an optical disk;

9A and 9B show light spots focused on two-phase and in-phase wobbling regions;

FIG. 10 is a diagram showing a high frequency signal detected from two-phase and in-phase wobbling regions by the light spot shown in FIG. 7; FIG.

FIG. 11 is a diagram showing a wobbling signal detected by the light spot shown in FIG. 7; FIG.

FIG. 12 is a diagram illustrating a high frequency signal generated by subtracting the wobbling signal shown in FIG. 11 from the high frequency signal shown in FIG.

FIG. 13 illustrates an apparatus for reproducing information stored in an optical disc according to an embodiment of the present invention. FIG.

14A and 14B illustrate a comparison process of the comparator shown in FIG. 13.

FIG. 15 illustrates an apparatus for reproducing information stored in an optical disc according to another embodiment of the present invention. FIG.

16A and 16B show signals detected by the band pass filter shown in FIG.

<Description of Symbols for Main Parts of Drawings>

10,20: Mountain signal track 12,22: Goal signal track

14: prepit row 24A: in-phase wobbling area

24B: Out of phase wobbling area 38, 42, 48: Wobble signal

30,32,34,62,63a, 63b, 64,66: light spot 62a, 62b: portion containing noise

36, 40, 46, 50, 54, 68, 70: high frequency signal 72: multiplier

74: subtractor 76: comparator

78: multiplexer 80,82,84,86: delay

88: band pass filter 90: subtractor

In order to achieve the above object, the information reproducing method of the optical recording medium of the present invention includes detecting a high frequency signal from a main spot, detecting a wobbling signal from a sub spot, and delaying the high frequency signal by a predetermined time for the wobble signal And subtracting the wobbling signal from the high frequency signal to remove noise mixed in the high frequency signal.

The information reproducing method of the optical recording medium of the present invention includes the steps of detecting a high frequency signal from the optical recording medium, band filtering the high frequency signal, delaying the high frequency signal by the time the high frequency signal is filtered, and delayed high frequency signal. Subtracting the filtered high frequency signal from the apparatus.

An information reproducing apparatus of an optical recording medium according to the present invention includes a first delayer for delaying the high frequency signal by a predetermined time in order to receive a high frequency signal detected from the main spot and to synchronize the wobble signal detected from the sub spot; A multiplier for multiplying the wobbling signal by a predetermined value in order to compensate for the difference in light intensity between the main spot and the sub spot by receiving the wobbling signal detected from the sub spot, and from the first high frequency signal and the multiplier output from the first delay unit A subtractor for receiving the output wobbling signal and subtracting the wobbling signal from the high frequency signal, and comparing the amplitude of the specified time of the wobbling signal with the amplitude after a predetermined time after receiving the wobble signal output from the multiplier A comparator for generating a control signal, and a first high frequency signal and a subtractor output from the first delay unit It receives the output from a second input for a control signal output from the high-frequency signal, and a comparator and a multiplexer for outputting any one of the first high-frequency signal and the second high-frequency signal under the control of the control signal.

An information reproducing apparatus of an optical recording medium of the present invention is a band pass filter for band filtering a high frequency signal detected from an optical recording medium, and for delaying the high frequency signal detected from the optical recording medium by a time for which the high frequency signal is band pass filtered. And a subtractor for receiving the high frequency signal and the filtered signal from the delay unit and the band pass filter, and subtracting the filtered signal from the high frequency signal.

Other objects and features of the present invention in addition to the above object will be apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 7 through 16B.

7 is a diagram showing a method of reproducing information stored in an optical recording medium according to an embodiment of the present invention.

Referring to FIG. 7, in the method of reproducing the optical recording medium of the present invention, the high frequency signal detected from the main spot 64 is delayed by a predetermined time Δt to synchronize with the wobbling signal detected from the second sub spot 62. Let's do it. Assuming that the main spot 64 is delayed by a predetermined time Δt, the second sub spot 62 is in-phase wobbling area 24A when the main spot 64 is located in the out-of-phase wobbling area 24B. ), And when the main spot 64 is located in the in-phase wobbling area 24A, the second sub spot 62 is located in the out-of-phase wobbling area 24B. That is, since the in-phase wobbling area 24A and the out-of-phase wobbling area 24B are alternately arranged in the width direction of the signal track, the main spot 64 and the second sub spot 62 delayed by a predetermined time Δt. ) Are always located in different wobbling regions. As described above, the main spot 64 and the second sub spot 62 are positioned up and down equally, and then are detected from the high frequency signal RF detected at the main spot 64, that is, the main spot 64 and delayed for a predetermined time. The noise mixed in the main spot 64 is removed by subtracting the wobbling signal W detected in the second sub spot 62 from the high frequency signal RF.

This will be described in detail with reference to FIGS. 8 to 12.

Frame wobbling system optical recording medium in-phase wobbling at a region (24A) is formed by a track width (T _p) constant in every zone as shown in Figure 8 are formed in phase. However, since the out-of-phase wobbling region 24B is formed out of phase, the out-of-phase wobbling region 24B is formed with a track width obtained by subtracting the amplitude P of the wobble from the track width T _p of the in-phase wobble region 24A. In other words, in the predetermined region, the two-phase wobble region 24B is formed with a track width obtained by subtracting the track width T _p and the amplitude P of the wobble. That is, the phase wobbling area (24B) in a given region is in the having a track width (T _p) and a track width of adding the amplitude (P) of the wobble (T _p + P) other areas the track width (T _p) The track width T _p -P is obtained by subtracting the amplitude P of the wobble. Thus, the biphasic wobbling region 24B is formed from a track width of T _p + P to a track width of T _p -P.

When the high frequency signal RF is detected from the in-phase wobbling region 24A, the high frequency signal 68 appears as shown in FIG. 10. In Equation 1 for detecting the high frequency signal 68, four photodetecting pieces Pa, Pb, Pc, and Pd are added to detect a high frequency signal. Therefore, the high frequency signal 68 in the in-phase wobbling region 24A in which the track width T _p is formed constantly appears constantly. However, when the high frequency signal RF is detected in the two-phase wobbling region 24B formed from the track width of T _p + P to the track width of T _p -P, a wide track width as shown in the high frequency signal 70 of FIG. It appears different in the part having (T _p + P) and in the part having a narrow track width (T _p -P). The high frequency signal 70 at the portion having a wide track width (T _p + P) appears larger than the high frequency signal 68 detected from the in-phase wobbling region 24A by a predetermined interval ΔR, and has a narrow track width. The high frequency signal 70 in the portion having (T _p -P) appears smaller by a predetermined interval ΔR than the high frequency signal 68 detected from the in-phase wobbling region 24A. As such, portions appearing larger or smaller than the high frequency signal 70 detected from the in-phase wobbling region 24A act as DC signals, that is, noise included in the out-of-phase wobbling region 24B.

On the other hand, as shown in Fig. 9A, the wobbling signal W detected when the light spot 63a is moved in the signal track direction of the out-of-phase wobbling area 24B becomes zero. In detail, since the two-phase wobbling regions 24B are formed in two phases, the first and fourth photodetecting pieces S2a and S2d and the second and third photodetecting pieces S2b and S2c are formed. The area is the same. Therefore, the wobbling signal W detected by Equation 2 becomes zero. However, in the in-phase wobbling region 24B, since both sides are formed in phase, the areas of the first and fourth photodetecting pieces S2a and S2d and the second and third photodetecting pieces S2b and S2c are different. Do. Accordingly, as shown in FIG. 9B, the wobbling signal W detected when the light spot 63b is moved in the signal track direction of the in-phase wobbling region is positive (+), “0” or negative polarity as shown in FIG. 11. It will have a value of (-).

That is, when the main spot 64 is located in the out-of-phase wobbling area 24B and the second sub spot 62 is located in the in-phase wobbling area 24A, as shown in FIG. ), A high frequency signal 70 as shown in FIG. 10 is detected, and a wobbling signal W as shown in FIG. 11 is detected from the in-phase wobbling region 24A. On the other hand, the intensity of light of the main spot 64 and the sub spots 62 and 66 is usually formed to be 1: 8: 1 or 1: 9: 1. Accordingly, if K (e.g., 8 or 9) times the high frequency signal 70 detected from the main spot 64 is subtracted from the wobbling signal W detected from the second sub spot 62, FIG. Likewise, a constant high frequency signal RF without noise is reproduced. Meanwhile, in the exemplary embodiment of the present invention, the high frequency signal RF detected from the main spot 64 is delayed by a predetermined time Δt to remove noise mixed in the high frequency signal RF. However, even when the wobble signal W detected from the first spot 66 is delayed by a predetermined time Δt, noise mixed in the high frequency signal RF can be removed.

FIG. 13 is a diagram illustrating an apparatus for reproducing information stored in an optical recording medium according to an exemplary embodiment of the present invention.

Referring to FIG. 13, an apparatus for reproducing information stored in an optical recording medium according to the present invention includes a first retarder 84 and a second sub spot receiving a high frequency signal R detected from a main spot 64. A multiplier 72 for receiving the wobbling signal Ws2 detected from 62; a second delayer 80 and a subtractor for receiving the high frequency signal R delayed by a predetermined time Δt from the first delayer 84; 74, a subtractor 74 and a comparator 76 which receive the wobbling signal Ws2 amplified by a predetermined multiple from the second multiplier 72, and a high frequency signal R output from the subtractor 74. The third delayer 82 and the multiplexer 78 for receiving the high frequency signals R delayed by the second delayer 80 and the third delayer 82 for a predetermined time period are provided. The first delay unit 84 outputs from the main spot 64 to synchronize the wobbling signal Ws2 output from the second sub spot 62 and the high frequency signal R output from the main spot 64. The high frequency signal R is delayed for a predetermined time [Delta] t. The multiplier 72 multiplies the wobbling signal Ws2 detected from the second sub spot 62 by a predetermined constant value K (for example, 8 or 9). That is, the multiplier 72 compensates for the difference in light intensity between the second sub spot 62 and the main spot 64. The wobbling signal Ws2 output from the multiplier 72 and the high frequency signal R output from the first delay unit 84 are input to the subtractor 74. In addition, the high frequency signal R output from the first delayer 84 is input to the second delayer 80, and the wobbling signal Ws2 output from the multiplier 72 is input to the comparator 76. . The subtractor 74 subtracts the wobbling signal Ws2 from the high frequency signal R. The signal output from the subtractor 74 is input to the third delayer 82. The comparator 76 compares the amplitude of the wobbling signal Ws2 and supplies a control signal of "0" or "1" to the multiplexer 78. The comparator 76 compares the wobbling signal W ₀ at a specific point in time with the wobbling signal W T / 4 at a point in time past _{T / 4} . That is, as shown in FIG. 14A, in the in-phase wobbling region 24A, the wobbling signal Ws2 is different between the wobbling signal W ₀ at a specific time point and the wobbling signal at the time point T / 4 past (here, T is the scanning time of the wobbling signal). As such, if there is a difference between the wobbling signal at a specific point in time and T / 4, that is, if W ₀ and W _{T / 4} are not the same, the comparator 76 sends a control signal of “0” to the multiplexer 78. Supply. The multiplexer 78 supplied with the control signal of "0" outputs an RF signal input from the second delay unit 80. On the other hand, when the phase Wars wobbling signal from the wobbling area (24B) (Ws2) as shown in Figure 14b is that the wobbling signal (W ₀₎ and T / 4 the wobbling signal (W _{T / 4)} of the last time at a point in time same. That is, as shown in FIG. 14B, in the out-of-phase wobbling region 24B, the wobbling signal Ws2 does not differ between the wobbling signal W ₀ at a specific time point and the wobbling signal at the time point T / 4 past (here, , T is the scanning time of the wobbling signal). As such, if there is no difference between the wobbling signals at a particular point in time and T / 4, that is, if W ₀ and W _{T / 4} are equal, the comparator 76 sends the control signal of &quot; 1 " to the multiplexer 78. Supply. The multiplexer 78 supplied with the control signal of "1" outputs an RF signal input from the third delay unit 82. Therefore, in the present invention, a wobbling signal mixed in the phase-phase wobbling region 24B, that is, a high frequency signal (RF signal) from which noise is removed can be obtained. Meanwhile, the second and third delayers 80 and 82 provided at the front end of the multiplexer 78 delay the high frequency signals R by T / 4 to synchronize them. A comparator (76) in the starting point (W ₀₎ and T / 4 the amplitude of the in Although comparing the phase difference between the amplitude (W _{T / 4)} of the last time, the last starting point (W ₀₎ and 3T / 4 time (W _{3T / 4} ) can also compare the phase difference. In this case, the second and third delayers 80 and 82 provided at the front end of the multiplexer 78 delay the high frequency signals R by 3T / 4 to synchronize.

15 is a diagram illustrating an apparatus for reproducing information stored in an optical recording medium according to another embodiment of the present invention.

Referring to FIG. 15, a reproducing apparatus according to another exemplary embodiment of the present invention may include a delay unit 86 and a band pass filter (hereinafter, referred to as “BPF”) that receive a high frequency signal R detected from the main spot 64. 88, and a subtractor 90 for receiving the output signal of the delayer 86 and the BPF 88. In the in-phase wobbling region 24A, the high frequency signal 68 emerges as shown in FIG. 10. On the other hand, the high frequency signal 70 detected in the out of phase wobbling region 24B appears differently depending on the track width as shown in FIG.

In detail, the high frequency signal R detected from the main spot 64 is input to the delay unit 86 and the BPF 88. The BPF 88 filters the input high frequency signal R. At this time, the high frequency signal R detected in the in-phase wobbling region 24A filtered by the BPF 88 appears as shown in FIG. 16A, and the high frequency signal R detected in the two-phase wobbling region 24B. As shown in Figure 16b has a positive (+), "0" or negative (-) value. The delayer 86 delays the high frequency signal R by the time filtered by the BPF 88. The signals output from the delayer 86 and the BPF 88 are input to the subtractor 90. The subtractor 90 subtracts the signal filtered by the BPF 88 from the high frequency signal R input from the delayer 86 and outputs a noise-free high frequency signal.

As described above, according to the method and apparatus for reproducing information of the optical recording medium according to the present invention, it is possible to remove the wobbling signal, that is, the noise, incorporated into the high frequency signal. Therefore, the amplitude of the wobble can be made large, and signal degradation due to reproduction and repetition of recording can be prevented.

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.

Claims (8)

An information recording method of an optical recording medium for reproducing information recorded on an optical recording medium by using a main spot and a sub spot located before and after the predetermined interval in a track different from the track where the main spot is collected. , Detecting a high frequency signal from the main spot; Detecting a wobbling signal from the sub spot; Delaying the high frequency signal by a predetermined time to synchronize the wobble signal; And subtracting the wobbling signal from the high frequency signal to remove noise mixed in the high frequency signal. The method of claim 1, And compensating for the difference between the light intensities of the main spot and the sub spot by multiplying the wobbling signal by a predetermined value. The method of claim 1, And subtracting the wobbling signal by the high frequency signal only in an area where both sides of the track of the optical record carrier are wobbed out of phase. An information recording apparatus of an optical recording medium having a main spot and a sub spot located before and after a predetermined distance from the main spot on a track different from the track where the main spot is collected, A first delay unit for delaying the high frequency signal by a predetermined time in order to receive the high frequency signal detected from the main spot and to synchronize the wobble signal detected from the sub spot; A multiplier that receives the wobbling signal detected from the sub spot and multiplies the wobbling signal by a predetermined value to compensate for a difference in light intensity between the main spot and the sub spot; A subtractor for receiving the first high frequency signal output from the first delayer and the wobbling signal output from the multiplier and subtracting the wobble signal from the high frequency signal; A comparator configured to receive a wobbling signal output from the multiplier and to generate a control signal by comparing the amplitude of the wobbling signal with the amplitude after a predetermined time; The first high frequency signal and the second high frequency signal are received by controlling the control signal by receiving a first high frequency signal output from the first delayer, a second high frequency signal output from the subtractor, and a control signal output from the comparator. And a multiplexer for outputting any one of the information reproducing apparatus. The method of claim 4, wherein The comparator compares the amplitude of the specified time of the wobbling signal with the wobbling signal of 1 / 4T (T is the scanning time of the wobbling signal) or 3 / 4T from the amplitude of the specified time. An information reproducing apparatus of a recording medium. The method of claim 4, wherein A second delayer for delaying the first high frequency signal output from the first delayer by a time for comparing the amplitude of the wobbling signal in the comparator; And a third retarder for delaying the second high frequency signal output from the multiplier by a time for comparing the amplitude of the wobbling signal in the comparator. A method of reproducing an optical record carrier having a track wobbling at a specific frequency, Detecting a high frequency signal from the optical record carrier; Band filtering the high frequency signal; Delaying the high frequency signal by a time for which the high frequency signal is filtered; Subtracting the filtered high frequency signal from the delayed high frequency signal And a reproduction method of an optical recording medium. An apparatus for reproducing an optical record carrier having a track wobbling at a specific frequency, A band pass filter for band filtering the high frequency signal detected from the optical record carrier; A delay unit for delaying the high frequency signal detected from the optical recording medium by the time when the high frequency signal is band filtered; And a subtractor for receiving the high frequency signal and the filtered signal from the delayer and the band pass filter and subtracting the filtered signal from the high frequency signal.