KR100269434B1 - Re-writable optical disc reproduction system and method therefor - Google Patents

Abstract

The present invention relates to a repeatable recordable optical disc reproducing system and method for reproducing with a weaker follow-up force than during data reproduction during header reproduction of each sector.

The present invention reduces the servo frequency band by reducing the servo frequency band during the transition from land to groove or from groove to land of the optical disc, thereby regenerating the header of each sector, and then at the moment when the optical spot enters the new data area. By reversing the phase of the tracking error signal so that the data can be reproduced with the compensator's first tracking power, the tracking error signal is prevented from growing during header playback, which is a problem of the prior art, and a phase signal instantaneous signal degradation of the tracking error signal occurs afterwards. Since the light spot is prevented from escaping to another track, sequential sector reproduction can be accurately performed, resulting in an improvement in reproduction quality.

Description

Method and system for reproducing a rewritable optical disk

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a repeatable recordable optical disc reproducing system and a method thereof, and more particularly to a repeatable recordable optical disc reproducing system and method for reproducing with reduced power following the reproduction of data of each sector.

Optical information storage devices have become the most effective solution among mass information storage media. However, the necessity of ultra high capacity is further increasing, and various methods for increasing capacity have been sought for optical discs to meet the demands of the times. In addition, studies on optical discs capable of repeatable recording and erasing have been actively conducted, and the appearance of recordable optical discs having a capacity of several Gbytes is on the horizon.

Repeatable recordable optical discs can be classified into two types, magneto-optical and phase change. Currently, several Gbytes are being studied and DVD-RAMs with 2.6Gbyte capacity are available. The standardization of the Digital Versatile Disk-Random Access Memory is expected to be finalized.

In general, a plurality of tracks for recording information are formed on the surface of a DVD-RAM, each track is divided into a plurality of sectors, and each sector has a header area in which an address signal, a synchronization signal, and the like are recorded, and a modulated data signal. Is divided into data areas to be recorded.

In addition, in the DVD-RAM, land / groove recording using a wobble signal is adopted to ensure reliability, such as that the address information characteristic does not deteriorate even when data recording is repeated many times in the user area. Doing. That is, in DVD-RAM, a plurality of lands and grooves are alternately formed in one track, and a header is formed between each land and groove.

Conventionally, after irradiating laser light to the surface of a rotating DVD-RAM, the light reflected from the DVD-RAM is received and converted into an electrical signal, and various information is reproduced using the electrical signal. In this case, in order to reproduce accurate information from the DVD-RAM, the optical spot must be accurately positioned at the center of the playback track of the DVD-RAM. For this purpose, the proposed method detects the light reflected from the DVD-RAM by using a quad split detector. A tracking error signal is generated, and the tracking error signal is compensated for by following all disturbances occurring in the DVD-RAM, and then provided to the pickup driver. Finally, the pickup driver drives the pickup actuator appropriately according to the signal provided to the optical spot. It is a technique to strengthen the power to follow the track, that is, the tracking power.

In addition, in the case of reproducing adjacent sectors on the same track in sequence, after reproducing each header, the phase of the tracking error signal must be inverted and compensated, and then provided to the pickup driver. This is because the tracking error signal when reproducing the land and reproducing the groove has a phase difference of 180 degrees due to the optical characteristic.

On the other hand, the header of each sector of the DVD-RAM is recorded interleaved in lands and grooves, so that the circumferential direction (from the center to the outside of the disc) and the circumferential direction (from the outside to the center of the disc) are precisely from the center line of the track. The header information is recorded so that 1/2 track pitches are shifted with each other.

Therefore, when the optical spot is moved along the centerline of a particular track by the rotation of the DVD-RAM and the information is reproduced while the tracking force in the land or groove remains in the header, the optical spot in the header is circumferential from the track's centerline. They come and go momentarily with 1/2 track pitch each in the inner circumferential direction.

However, such a prior art has a strong following power when the optical spot (pickup) that generates the light spot is damaged while the light spot transitions from land to groove or from groove to land, i.e. while regenerating the header of each sector. As a result, a large tracking error signal is generated and the overshoot becomes large. Then, a phase inversion of the tracking error signal causes an instantaneous signal deterioration, which causes the optical spot to deviate to another track, thereby making it impossible to sequentially reproduce the sectors. There was a problem falling.

Accordingly, the present invention reduces the tracking power by reducing the servo frequency band during the transition from land to groove or from groove to land, that is, during the reproduction of the header of each sector, and then tracking at the moment when the optical spot enters the new data area. SUMMARY OF THE INVENTION An object of the present invention is to provide a repeatable recordable optical disc reproducing system and method for reversing the phase of an error signal so that data can be reproduced with a compensator first tracking power.

In order to achieve the above object, a repeatable recordable optical disc reproducing system according to the present invention reproduces repeating recordable optical discs in which a plurality of lands and grooves are alternately formed in one track and a header is formed between each land and groove. A system comprising: a tracking error signal generator for generating a tracking error signal from light reflected by said optical disc, a data signal generator for generating a data signal from light reflected by said optical disc, and all disturbances generated by said optical disc. A signal compensator for tracking and compensating for the input signal, a low pass filter for reducing the frequency band of the input signal to weaken the following power, and supplying the signal to the signal compensator; Detects the header at the beginning of playback of the header A microcomputer for supplying the tracking error signal to a filter and outputting a control signal for supplying the tracking error signal to the signal compensator at the time point at which the header is regenerated; And a first switching unit configured to supply the tracking error signal to one of a signal compensator and the low pass filter.

The signal compensator includes a read-lag compensator for compensating for an input signal by following all disturbances generated in the optical disc; An inverting amplifier inverting a phase of an input signal and supplying it to the read-lag compensator; If the current land is being reproduced by switching under the control of the microcomputer, the output signal of the tracking error signal generation unit or the output signal of the low pass filter input through the first switching unit is supplied to the read-lag compensator. Preferably, the groove is configured with a second switching unit for supplying the output signal to the inverting amplifier.

Further, the repeatable recordable optical disc reproducing method according to the present invention is a method of reproducing a repeatable recordable optical disc in which a plurality of lands and grooves are alternately formed in one track and a header is formed between each land and groove. A first step of determining which part of the current land, groove, or header is being reproduced by using the data signal generated from the light reflected by the second step; A second step of compensating for the tracking error signal generated from the light reflected from the optical disk following all disturbances generated in the optical disk when the land is being reproduced as a result of the determination of the first step to enhance the tracking power; A third step of reducing the tracking power by reducing the frequency band of the tracking error signal during the header reproduction period if the header is being reproduced as a result of the determination in the first step; If the groove is being reproduced as a result of the first step, a fourth step of reinforcing and compensating for the tracking error signal during the groove reproducing period may be provided.

1 is a partial plan view of a typical DVD-RAM;

2 is a block diagram showing a part of a configuration of a DVD-RAM reproducing system according to an embodiment of the present invention;

3 is a diagram illustrating a mutual relationship between a DVD-RAM, a tracking error signal TE, and a data signal RF;

4 is a frequency characteristic diagram of a transfer function of the lead-lag compensator shown in FIG. 2;

5A is an open loop characteristic diagram of a system in land or groove regeneration;

5B is an open loop characteristic diagram of a system during header reproduction.

<Explanation of symbols for the main parts of the drawings>

10: 4-split optical detector 20: tracking error signal generator

30: data signal generation unit 40: signal compensation unit

41: lead-lag compensator 42: inverting amplifier

43: second switching unit 50: low pass filter

60: microcomputer 70: second switching unit

80: pickup drive unit

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

1 is a plan view of a general DVD-RAM, in which each track is divided into a plurality of sectors, each of which includes a header area in which an address signal, a synchronization signal, and the like are recorded, and a modulated data signal. It is divided into data areas.

In the above, address information of each sector is recorded in a header as a pit. The header is recorded interlocking with lands and grooves as shown in FIG. That is, in the case of lands, addresses 1 and 2 are arranged so that 1/2 track pitch is shifted from the center line of the track to the outer circumferential direction, and addresses 3 and 4 are arranged so as to shift 1/2 track pitch from the center line of the track to the inner circumferential direction. do. In the case of grooves, addresses are arranged in the inner circumferential direction and addresses 3 and 4 in the outer circumferential direction as opposed to the land. Here, address 1 and address 2, address 3 and address 4 are the same information to minimize physical errors. In addition, address 1 and address 2 represent sector addresses of subsequent lands, address 3 and address 4 represent sector addresses of subsequent grooves, and the four addresses are logically configured to know the remaining addresses if only one of them is known. have.

In the above data sector, the recording film of the disk is changed into two phases, crystalline and amorphous, by the heat of the laser, so that each corresponds to '1' and '0'. Data is recorded, and information is read at the time of reproduction by the difference in the amount of reflection from the disk surface, wherein the amount of reflection in the crystalline state is larger than the amount of reflection in the amorphous state.

On the other hand, when the current optical spot is located on a land when the DVD-RAM switches from the current sector to the next sector in the format of the disc, the optical spot plays the groove after passing the header of the next sector. If the spot location is on the groove, the light spot is to reclaim the land after passing the header of the next sector.

In addition, the tracking error signal when reproducing the land and reproducing the groove has a phase difference of 180 degrees due to the optical characteristics. Therefore, if the current light spot is located in the land, it is necessary to invert the phase of the tracking error signal when the header reproduction is completed.

In addition, as shown in FIG. 1, it is necessary to weaken the tracking force while the header is being reproduced in order to allow the tracking path of the optical spot to move along the track center without deviating from the track center (prior art) in the header of each sector. Do.

FIG. 2 is a block diagram illustrating a part of a DVD-RAM reproducing system according to an exemplary embodiment of the present invention, wherein the DVD-RAM reproducing system includes a four-segment photodetector 10, a tracking error signal generator 20, And a data signal generator 30, a signal compensator 40, a low pass filter (LPF) 50, a microcomputer 60, a first switching unit 70, and a pickup driver 80. Doing.

When the light reflected from the rotating DVD-RAM (not shown) surface is incident through the pickup (not shown), the four-segment photodetector 10 detects and respectively corresponds to the amount of light that is incident on it. Four light receiving elements A, B, C, and D output the electrical signals to the tracking error signal generator 20 and the data signal generator 30, respectively.

The tracking error signal generator 20 is an electrical signal input from each of the four light receiving elements A, B, C, and D of the 4-split photodetector 10 (for convenience, referred to as A, B, C, and D). Is calculated as in Equation 1 below to generate a tracking error signal (TE). As shown in FIG. 3, the tracking error signal TE is a sine wave which becomes zero at the centers of the land and the grooves, and is a signal that enables the detection of the positional shift between the center of the reproduction track and the center of the optical spot of the DVD-RAM. .

TE = (A + D)-(B + C)

The data signal generator 30 calculates an electrical signal input from each of the four light receiving elements A, B, C, and D of the 4-split photodetector 10 as shown in Equation 2 below. Generate a data signal RF. As illustrated in FIG. 3, the data signal RF is a sinusoidal wave having a phase difference of 90 ° from the tracking error signal TE.

RF = A + B + C + D

The signal compensator 40 complies with all disturbances generated in the DVD-RAM to compensate for the input signal and outputs it to the pickup driver 80. Specifically, the signal compensator 40 includes a lead-lag compensator 41, an inverting amplifier 42, and a second switching unit 43.

The read-lag compensator 41 complies with all disturbances generated in the DVD-RAM and compensates the input signal and outputs it to the pickup driver 80. The transfer function D (S) of the lead-lag compensator 41 is defined as in Equation 3 below, and has a frequency characteristic as shown in FIG. 4. In FIG. 4, a1 is 10 Hz to 20 Hz, b1 is 100 Hz to 200 Hz, b2 is 800 Hz to 1 KHz, and a2 is 11 KHz to 15 KHz. The lead-lag compensator 41 having the characteristics as shown in FIG. 4 is a compensator that stabilizes the tracking loop and secures a predetermined servo frequency band.

The inverting amplifier 42 inverts the phase of the input signal and supplies it to the read-lag compensator 41.

The second switching unit 43 switches under the control of the microcomputer 60, and if the current land is being reproduced, the output signal TE of the tracking error signal generation unit 20 input through the first switching unit 70. When the output signal of the low pass filter LPF, 50 is supplied to the lead-lag compensator 41, and the groove is currently being reproduced, the output signal TE of the tracking error signal generator 20 or the low pass filter ( The output signal of the LPF 50 is supplied to the inverting amplifier 42.

The low pass filter LPF 50 reduces the frequency band of the input signal to weaken the tracking power and then supplies it to the second switching unit 43 of the signal compensator 40.

The microcomputer 60 detects a header start time and a playback end time from the data signal RF output from the data signal generator 30 and tracks the low pass filter LPF 50 at the header start time. The tracking error signal TE output from the error signal generator 20 is supplied, and the tracking error signal TE is supplied to the second switching unit 43 of the signal compensator 40 when the header is regenerated. Outputs a control signal to be supplied.

The first switching unit 70 switches according to the control signal of the microcomputer 60 to generate a tracking error signal in one of the second switching unit 43 and the low pass filter LPF 50 of the signal compensator 40. The tracking error signal TE output from the unit 20 is supplied.

The pickup driver 80 drives a pickup actuator (not shown) in accordance with the output signal from the lead-lag compensator 41 of the signal compensator 40 so that the center of the optical spot emitted from the pickup is located in the track. Move the pickup properly to align with the centerline.

Referring to the operation of the DVD-RAM reproducing system according to an embodiment of the present invention configured as described above in detail as follows.

First, when the light reflected from the surface of the rotating DVD-RAM (not shown in the drawing) is incident on the four light receiving elements A, B, C, and D of the four-segment photodetector 10, the respective light receiving elements ( A, B, C, and D detect the amount of light incident on the self and transmit the corresponding electric signals A, B, C, and D to the tracking error signal generator 20 and the data signal generator 30. Print each.

The tracking error signal generator 20 calculates the tracking error signal TE by calculating the electrical signals A, B, C, and D received from the four-segment photodetector 10 as shown in Equation 1 below. ), And the data signal generator 30 calculates the electrical signals A, B, C, and D received from the four-segment photodetector 10 as shown in Equation 2, thereby calculating the data signal ( Generate RF).

On the other hand, the microcomputer 60 receives the data signal RF output from the data signal generator 30 and determines which part of the current land, groove, and header is being reproduced. This can be easily determined through the header information (information recorded in the address prepit) of each sector reproduced.

First, when the land is regenerated as a result of the determination, the microcomputer 60 controls the first switching unit 70 and the second switching unit 43 to control the tracking error signal generation unit 20 by the first switching unit 70. ) And the second switching unit 43 are connected, and the second switching unit 43 is connected between the first switching unit 70 and the rig-lag compensator 41 so that the tracking error signal TE is generated. Direct input into the league-lag compensator 41. The rig-lag compensator 41 compensates for all disturbances generated on the DVD-RAM by compensating for the received tracking error signal TE and outputs the compensation to the pickup driver 80. As described above, the characteristics of the servo system including the rig-lag compensator 41 and the pick-up actuator during the land regeneration are very large in tracking power due to the wide frequency band as shown in FIG. 5A.

Second, when the header is reproduced as a result of the determination, the microcomputer 60 controls the first switching unit 70 and the second switching unit 43 to control the tracking error signal generation unit 20 by the first switching unit 70. ) Is connected between the low pass filter LPF and 50, and between the low pass filter LPF and the rig-lag compensator 41 by the second switching unit 43. ) Is input to the rig-lag compensator 41 after the frequency band is reduced by the low pass filter LPF 50. The lag-lag compensator 41 tracks a tracking error signal having a reduced frequency band to compensate for all disturbances occurring on the DVD-RAM and outputs the compensation to the pickup driver 80. As such, the characteristics of the servo system including the rig-lag compensator 41 and the pickup actuator while the head is being regenerated have a lower frequency band than the regeneration of the land due to the low pass filter LPF 50 as shown in FIG. 5B. Eventually the following power is lowered. Therefore, even while the header is reproduced, the light spot moves along the centerline of the track as shown in FIG.

Third, if the groove is being reproduced as a result of the determination, the microcomputer 60 controls the first switching unit 70 and the second switching unit 43 to control the tracking error signal generation unit 20 by the first switching unit 70. ) And the second switching unit 43 are connected, and the second switching unit 43 is connected between the first switching unit 70 and the inverting amplifier 42 so that the tracking error signal TE is inverted. The phase is reversed by 42 and then input to the rig-lag compensator 41. The lag-lag compensator 41 compensates for all disturbances generated on the DVD-RAM by compensating for the received phase-inverted tracking error signal TE and outputs it to the pickup driver 80. The characteristics of the servo system including the rig-lag compensator 41 and the pick-up actuator while the groove is being reproduced in the same manner as in the case where the lag is being reproduced, that is, as shown in FIG. very big.

In other words, the microcomputer 60 detects the start time and the completion time of playback of the land, the groove, and the header by using the data signal RF, and the tracking error signal generator 20 outputs the tracking error while the land is being reproduced. The error signal TE is directly input to the rig-lag compensator 41, and the tracking error signal TE output from the tracking error signal generator 20 is the low pass filter LPF 50 while the header is reproduced. Is inputted to the rig-lag compensator 41 via the lag compensator 41, and the tracking error signal TE output from the tracking error signal generator 20 passes through the inverting amplifier 42 via the rig-lag compensator 41 while the groove is reproduced. To be entered.

In addition, the switching operation of the first switching unit 70 and the second switching unit 43 should be made within a short time in a range that does not impair the stability of the system.

As a result of the above operation, as shown in FIG. 1, the optical spot moves along the center line of the track as in the case of playing the land or the groove, even when the header is played, thereby preventing signal degradation, which has been pointed out as a problem of the prior art. Departures to other tracks are also prevented.

Meanwhile, in another embodiment of the present invention, instead of inverting the phase of the tracking error signal as in the embodiment of the present invention, two different rig-lag compensators that reflect the characteristics of the land and the grooves, that is, a land regeneration dedicated compensator and a groove, are used. The regeneration compensator may be separately provided so that the compensator may be used at the start of the regeneration of the land or the regeneration of the groove. This can easily be achieved using a switching element, and the compensator switching must be done within a short time without compromising system stability.

As described above, the present invention weakens the tracking power while reproducing the header of each sector, thereby preventing the tracking error signal from becoming large during the header regeneration, thereby preventing the signal deterioration of the tracking error signal from occurring. Deviation is prevented, and sequential sector reproducing is performed accurately, resulting in an improvement in reproducing quality.

Claims (3)

In a system for reproducing a repeatable recordable optical disc in which a plurality of lands and grooves are alternately formed in one track and a header is formed between each land and groove, A tracking error signal generator for generating a tracking error signal from the light reflected by the optical disc; A data signal generator for generating a data signal from the light reflected by the optical disc; A signal compensator for compensating for an input signal by following all disturbances generated in the optical disc; A low pass filter for reducing the frequency band of the input signal to weaken the tracking power and supplying the signal to the signal compensator; When the reproduction start time and the reproduction completion time of the header are sensed from the data signal, the tracking error signal is supplied to the low pass filter at the time when the header starts to be reproduced. A microcomputer that outputs a control signal for supplying a tracking error signal; And a first switching unit configured to switch according to the control signal of the microcomputer to supply the tracking error signal to one of the signal compensator and the low pass filter. The method of claim 1, The signal compensator includes a read-lag compensator for compensating for an input signal by following all disturbances generated in the optical disc; An inverting amplifier inverting a phase of an input signal and supplying it to the read-lag compensator; If the current land is being reproduced by switching under the control of the microcomputer, the output signal of the tracking error signal generation unit or the output signal of the low pass filter input through the first switching unit is supplied to the read-lag compensator. And a second switching unit for supplying the output signal to the inverting amplifier when a groove is being reproduced. In a method for reproducing a repeatable recordable optical disc in which a plurality of lands and grooves are alternately formed in one track and a header is formed between each land and groove, A first step of determining which part of a land, a groove, a header is currently reproduced by using a data signal generated from the light reflected from the optical disc; A second step of compensating for the tracking error signal generated from the light reflected from the optical disk following all disturbances generated in the optical disk when the land is being reproduced as a result of the determination of the first step to enhance the tracking power; A third step of reducing the tracking power by reducing the frequency band of the tracking error signal during the header reproduction period if the header is being reproduced as a result of the determination in the first step; And a fourth step of reinforcing and compensating for the tracking error signal during the groove reproducing period when the groove is being reproduced as a result of the first step.