KR100192436B1 - Optical disc recorder and recording method - Google Patents

Abstract

An optical disk recording and reproducing apparatus for overcoming an external obstacle occurring during recording, and a recording method thereof, comprising: a code conversion unit for decoding an ATPI signal and recording data of an ATIP generation unit, and detecting the shank from the ATIP signal decoded by the code conversion unit An optical disk recording and reproducing apparatus including a check error counter unit for counting a predetermined time until the occurrence of the detected shank signal and outputting a control signal, and a power adjusting unit performing a recording mode according to the control signal of the check error counter unit; And initializing the shank error counter to record data on the optical disc, calculating an error position of the optical disc by generating a recording error on the optical disc, and sequentially recording from the error position of the optical disc. By providing an optical disc recording method, To improve, and even if the recording error can quickly find perform continuous recording error location.

Description

Optical disc recorder and recording method

The present invention relates to an optical disc recording and reproducing apparatus and method, and more particularly, to an optical disc recording and reproducing apparatus and a recording method thereof for overcoming an external obstacle occurring during recording. In general, in the case of recording and reproducing data on an optical disc, the optical recording player stops the recording operation as soon as an error is detected when a shank occurs due to an external failure, and the track in which the error occurs becomes an unusable area.

Hereinafter, an optical disc recording and reproducing apparatus according to the prior art will be described with reference to the accompanying drawings.

1 is a block diagram showing an optical disk recording and reproducing apparatus according to the prior art. In the conventional optical disc recording and reproducing apparatus, as shown in FIG. 1, an optical pickup 1 for reading data from an optical disc and an error generating unit 2 for generating focus and tracking error signals from the data of the optical pickup 1 are provided. ), An RF generator 3 for generating an EFM signal from the data of the optical pickup 1, an ATIP generator 4 for generating an ATIP synchronization signal from the data of the optical pickup 1, and the optical A REC generator 5 for generating a REC parameter signal from the data of the pickup 1, a servo processor 6 for signal processing the EFM signal of the error generator 2, and outputting a servo signal; A digital signal processor 7 for decoding the servo signal of the servo processor 6 to output the servo control signal, and decoding and outputting the EFM signal of the RF generator 3; and the digital signal processor 7 Servo control signal and EFM signal of the error generating unit 2 and the servo processing A drive unit 8 for driving the motor to rotate the optical disc in response to the servo signal of (6), driving the focusing and tracking of the optical pickup 1, and driving the motor to move the optical pickup 1; A shank detector 9 for detecting an external disturbance shank from the servo signal of the servo processor 6, and an audio processor 10 for processing the EFM signal decoded by the digital signal processor 7 as an audio signal; The microcomputer 11 receives the REC parameter signal of the REC generator 5 and the shank signal of the shank detection unit 9, outputs a recording control signal, and controls the system bottom, and the ATIP generator 4 A code converter 12 for decoding and outputting an ATIP synchronous signal to the driver 8 and encoding and decoding a composite video signal, and interfacing the code video to the code converter 12 after receiving the composite video signal from a host. Interface unit 13 and the code A data modulator 14 for modulating the composite video signal encoded by the converter 12 into recording data, and data of the data modulator 14 by the recording control signal of the microcomputer 11. 1) adjusts the power to write on the optical disk, and receives the check signal of the shank detection unit 9, and the power control unit 15 stops the power supply.

The operation according to the prior art configured as described above, first, when the optical pickup 1 is driven by the drive unit 8 to read data from the optical disk, the error generating unit 2 generates a focus and tracking error from the data. It outputs to the drive part 8, and outputs to the servo signal processing part 6. As shown in FIG.

The servo signal processor 6 receives and processes the output of the error generator 2, outputs the servo signal to the digital signal processor 7, outputs it to the shank detector 9, and drives the driver 8. Output a control signal.

At this time, the RF generator 3 generates an EFM signal from the optical pickup 1 and outputs the EFM signal to the digital signal processor 7.

The driver 8 receives the output of the error generator 2, the servo signal processor 6, and the digital signal processor 10 to servo control a motor for rotating the optical disc, and the optical pickup 1 Servo control of the motor for transporting the motor and control of focusing and tracking of the optical pickup 1 allows the system to stably read data from the optical disk.

Then, the digital signal processing unit 7 receives the servo signal, processes the digital signal, outputs the servo control signal to the driving unit 8, and digitally processes the EFM signal and decodes the EFM signal to demodulate the audio signal. Output to the audio processing unit 10.

Subsequently, the audio processor 10 processes the signal so that the demodulated audio signal is reproduced as sound.

In addition, when the EFM signal is ROM data, it is input to the code conversion unit 12 to correct and decode ROM data for error correction, and the data is input to the host computer through the interface unit 13 to receive data. Processing for reproduction is performed.

On the other hand, when recording an optical disk, spindle control is performed by a wobble signal from the recording disk.

That is, the data is read from the optical pickup 1, the ATIP generation unit 4 generates the ATIP synchronous signal, and inputs the code conversion unit 12 to decode the internal ATIP decoder to drive the spindle control signal of the recording disk. Send to (8). Subsequently, the optical pickup 1 is controlled by the drive section 8 to read its own information for recording on the disc.

The self information is then input to the power control unit 15 to create a recording ready state.

When data information of the host is recorded on the optical disk, the host data is input to the code conversion unit 12 through the interface unit 13 and the data is encoded.

At this time, the encoded data is input to the data modulator 14, and then input to the power control unit 15, which is processed into a signal form suitable for recording according to the characteristics of the recording medium, and is in a ready state for recording. The adjusting unit 15 receives the recording control signal of the microcomputer 11 and adjusts the intensity of the laser light so that the data is recorded on the optical disk through the optical pickup 1.

The data can be recorded on the optical disk by the laser light thus adjusted.

Here, first, the recording condition is extracted from the optical pickup 1 by the power adjusting unit 15 and the REC generating unit 5 as a condition to be preceded, and inputted into the microcomputer 11 by the microcomputer 11 by this condition. Outputs a recording control signal to the power adjusting section 15.

On the other hand, if a recording error occurs due to the shank or the like while data is being recorded by the power control unit 15, the shank detection unit 9 detects the shank from the servo signal of the servo signal processing unit 6 to adjust the power. The laser light output of the unit 15 is stopped and the microcomputer 11 is notified of the shank occurrence.

This performing function prevents the recording error, that is, miswriting, from occurring beyond the recording point of the disc by the shank.

In general, when a recording error occurs as described above, the hardware of the system cannot perform error correction independently, and the disk can be recovered with the help of software.

In other words, the system cannot record the data to the end of the track and update the system memory area (PMA). Therefore, the track in which the error occurred during the recording is meaningless, and it is a obstacle to grasping the contents of the disc. Becomes

Therefore, with the help of the software, the recording stop track is displayed in the system area so that the recording error can be corrected for further recording in the subsequent area.

Conventional optical recording / reproducing apparatus has a problem in data transfer from the host when the recording point is deviated by the shank from the outside, and the buffer used by the code conversion section 12 becomes empty and the recording is performed due to abnormal power. In this case, the recording mode may be interrupted.

Therefore, if a recording error occurs as described above, the track in which the error occurred in the file structure of the current recorder does not record all the necessary data information, and thus becomes a playable track.

This is a problem that the efficiency of the recording disk is inferior and replaces the convenience of the user. SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide an optical disc recording and reproducing apparatus for determining the exact recording point where a recording error occurs and performing continuous recording from this position.

1 is a block diagram showing an optical disk recording and reproducing apparatus according to the prior art.

2 is a block diagram showing an optical disk recording and reproducing apparatus according to the present invention.

3 is a detailed view showing an error counter according to the present invention in detail.

4 is a timing diagram illustrating an operation according to the present invention.

5 is a flowchart showing an optical disc recording method according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Optical pickup 2: Error generating unit

3: RF generator 4: ATIP generator

5: REC generation unit 6: Servo processing unit

7 digital signal processor 8 driver

9: Shank detection unit 10: Audio processing unit

11: microcomputer 12: code conversion unit

13 interface unit 14 data modulation unit

15: power control unit 18: check error counter unit

The present invention is a code conversion unit for decoding the ATIP signal and the recording data of the ATIP generation unit, outputting a control signal by counting a predetermined time from the ATIP signal decoded by the code conversion unit to the generation of the shank signal detected by the link detection unit An optical disc recording and reproducing apparatus including a check error counter section, a power adjusting section for performing a recording mode according to a control signal of the check error counter section, and initializing the check error counter section to record data on the optical disk, the optical It is possible to improve the efficiency of using an optical disc by providing an optical disc recording method comprising the step of calculating an error position of an optical disc due to a recording error on the disc, and subsequently recording from the error watch of the optical disc. Even if a recording error occurs, the error location is quickly found and continuous recording is performed. There is a feature that can be performed.

Hereinafter, an optical disc recording / reproducing apparatus and a recording method thereof according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram showing an optical disk recording and reproducing apparatus according to the present invention, FIG. 3 is a detailed view showing an error counter according to the present invention in detail, and FIG. 4 is a timing chart showing an operation according to the present invention. 5 is a flowchart showing an optical disc recording method according to the present invention.

In the optical disk recording and reproducing apparatus according to the present invention, as shown in the second operation, an optical pickup 1 for reading data from an optical disk and an error for generating focus and tracking error signals from the data of the optical pickup 1 A generator 2, an RF generator 3 for generating an EFM signal from the data of the optical pickup 1, and an ATIP generator 4 for generating an ATIP synchronous signal from the data of the optical pickup 1 And a REC generator 5 for generating a REC parameter from the data of the optical pickup 1, and a servo signal processor 6 for processing the EFM signal of the error generator 2 to output a servo signal. And a digital signal processor 7 for decoding the servo signal of the servo signal processor 6 to output the servo control signal, and decoding and outputting the EFM signal of the RF generator 3, and the digital signal. The servo control signal of the processing unit 7 and the EFM signal of the error generation unit 2 Receiving a servo signal of the servo signal processing unit 6 of the motor to drive the motor to rotate the optical disk, driving the focusing and tracking of the optical pickup (1) and driving the motor to move the optical pickup (1) A shank detection unit 9 for detecting an external obstacle shank in the servo signal of the driver 8 and the servo signal processing unit 6, and an EFM signal decoded by the digital signal processing unit 7 as an audio signal. A microcomputer 11 which receives an audio processor 10, a REC parameter signal of the REC generator 5, and a shank signal of the shank detection unit 9, outputs a recording control signal, and controls the system body; A code converter 12 which decodes the ATIP synchronization signal of the generator 4 and outputs it to the driver 8, encodes and decodes the composite video signal, and outputs the composite video signal from a host. Interfacing with (12) An interface unit 13, a data modulator 14 for modulating the composite video signal encoded by the code converter 12 into recording data, and the data modulator (B) by a recording control signal of the microcomputer 11; A power control unit 15 for adjusting the power of the optical pickup 1 to record the data of the optical disc 14 on the optical disk and stopping by the power supply stop signal, and decoded by the code conversion unit 12; Shank for counting the time from the start point of the ATIP synchronization signal until the shank signal of the shank detection unit 9 is generated, outputting the signal to the microcomputer 11, and outputting the power supply stop signal to the power control unit 15. It consists of an error counter 18.

As shown in FIG. 3, the shank error counter unit 18 is operated by various enable and operation signals, and receives the ATIP synchronization signal decoded by the code conversion unit 12 to clear the count value. A count and register unit for counting the time from the clear to the shank detection signal is generated, and the ATIP synchronization signal is switched by the control signals of the NOR gate and the microcomputer 11 to be outputted to the count and register unit. It consists of a switching unit.

In the operation according to the present invention configured as described above, first, the optical pickup 1 is driven by the driving unit 8 to read data from the optical disk, and the error generating unit 2 generates focus and tracking errors from the data. It outputs to the drive part 8, and outputs to the servo signal processing part 6. As shown in FIG.

The servo signal processor 6 receives and processes the output of the error generator 2, outputs the servo signal to the digital signal processor 7, outputs it to the shank detector 9, and drives the driver 8. Output a control signal.

At this time, the RF generator 3 generates an EFM signal from the optical pickup 1 and outputs the EFM signal to the digital signal processor 7.

The driver 8 receives the output of the error generator 2, the servo signal processor 6, and the digital signal processor 10 to servo control a motor for rotating the optical disc, and the optical pickup 1 Servo control of the motor for transporting the motor and control of focusing and tracking of the optical pickup 1 allows the system to stably read data from the optical disk.

The digital signal processor 7 receives the servo signal, processes the digital signal, outputs the servo control signal to the driver 8, and digitally processes and EFM decodes the EFM signal to demodulate the audio signal. Output to the processing unit 10.

Subsequently, the audio processor 10 processes the signal so that the demodulated audio signal is reproduced as sound.

In addition, when the EFM signal is ROM data, it is input to the code conversion unit 12 to correct and decode ROM data for error correction, and the data is input to the host computer through the interface unit 13 to receive data. Processing for reproduction is performed.

Thus, it can be seen that the above description is made in the same manner as the operation according to the prior art. On the other hand, when recording an optical disk, spindle control is performed by a wobble signal from the recording disk.

That is, the data is read from the optical pickup 1, the ATIP generating unit 4 generates an ATIP synchronous signal, and inputs it to the code conversion unit 12. The ATIP decoder decodes an internal ATIP decoder to drive the spindle control signal of the recording disk. Send to (8). Subsequently, the optical pickup 1 is controlled by the drive section 8 to read its own information for recording on the disc.

The self information is then input to the power control unit 15 to create a recording ready state.

The ATIP synchronous signal decoded by the code conversion unit 12 is recognized by the check error counter unit 18 to clear the count value, and the time count is started again from the clear point.

Subsequently, when the data information of the host is recorded on the optical disk, the host data is input to the code conversion unit 12 through the interface unit 13 and the data is encoded.

At this time, the encoded data is input to the data modulator 14, and then input to the power control unit 15, which is processed into a signal form suitable for recording according to the characteristics of the recording medium, and is in a ready state for recording. The adjusting unit 15 receives the recording control signal of the microcomputer 11 and adjusts the intensity of the laser light so that the data is recorded on the optical disk through the optical pickup 1.

The data can be recorded on the optical disk in the laser light thus adjusted.

Here, the power conditioner 15 and the REC generator 5 extract the recording condition from the optical pickup 1 and input it to the microcomputer 11 as a precondition to be preceded first. Outputs a recording control signal to the power adjusting section 15.

On the other hand, while data is being recorded by the power control unit 15, i.e., during the time counting since the clear time of the check error counter unit 18, which clears and time counts the count value by the ATIP synchronization signal, When a recording error occurs due to an external disturbance, the shank detection unit 9 detects the shank from the servo signal of the servo signal processing unit 6 to inform the microcomputer 11 of the shank occurrence and the shank error counter unit 18. To pass on.

Subsequently, the shank error counter unit 18 stops the laser light output of the power adjusting unit 15 and stores a count value at which a recording error occurs.

Referring to the drawing shown in FIG. 4, the shank error counter unit 18 will be described in more detail. The rising edge of the recording clock is continuously counted from the time point at which the ATIP synchronization signal is generated during recording.

At this time, the count value is cleared every time the ATIP synchronization signal is generated, and the count is repeated. However, if a recording error occurs due to the shank during recording in this manner, the shank detection signal through the shank detection unit 9 is input to the shank error counter unit 18 to stop the counting operation.

Then, the check error counter 18 transmits an interrupt signal to the microcomputer 11 and outputs the count value of the recording error to the microcomputer 11.

In addition, if a recording error occurs because the data is emptied in the buffer during recording, the microcomputer 11 can recognize an empty sector from the disk, so that the error position of the error track is applied until the Prepit signal is applied while playing the track. The check error counter unit 18 counts from the start point of the ATIP synchronous signal and stops counting when the prepit signal is applied.

The prepit signal is usually included in a PMA signal. When the data is recorded, the prepit signal indicates a low signal, but when the data is not recorded, the prepit signal indicates a high signal.

Then, the check error counter unit 18 transmits an interrupt signal to the microcomputer 11 to output the count value of the recording error to the microcomputer 11.

In addition, if a recording error occurs due to a power off during the recording, or a power interruption, the prepit signal checks whether data has been recorded since the last track recorded in the disc's PMA area. Judging by the point. The operation of finding the position of the recording error is the same as the method of recognizing the count value using the prepit signal.

As described above, in order to continuously record and correct a recording error due to a disorder such as a check, the data is output in accordance with the ATIP synchronization signal where a recording error occurs, and the recording mode is changed from the occurrence of the ATIP synchronization signal to the count value at which an error occurs. After proceeding, the recording of the disk can be performed continuously by the operation of the power adjusting unit 15 from the time of occurrence of the error.

In the recording method of the optical recording and reproducing apparatus according to the present invention, as shown in FIG. 5, the recording error generated by the check error counter unit 18 before starting recording by the recording path by the microcomputer 11 is performed. The count value is initialized with the ATIP synchronous signal and data recording is started with the recording path from the code conversion section 12 to the power control section 15.

At this time, if a write error occurs due to the shank during recording, the shank interrupt loop is executed. That is, when the shank detection signal through the shank detection unit 9 is input to the shank error counter unit 18, the counting operation is stopped, and the shank error counter unit 18 from the microcomputer 11 to the point where an error occurs is generated. Read the count value of.

Then, an error sector of the optical disk on which the ATIP signal is generated is calculated from the error count value to obtain an error position value T from the ATIP reproduction signal to the error occurrence point.

At this time, the record data for recording is output while finding the position of the error sector of the disk on which the ATIP signal is generated.

Subsequently, the counter error counter unit 18 counts down to the error position value T from the point where the ATIP signal is generated, and operates the power control unit 15 from the point where the error position value becomes 0 to continue recording. Perform the mode.

In addition, if a recording error occurs due to power off during recording, a power halt interrupt loop is executed.

That is, the optical disk being recorded is moved to the previous area where the recording error occurs, and the count value is continued from the ATIP signal generation point of the PMA area of the optical disk to the prepit signal generation point (recording error occurrence point) in the playback mode. To calculate.

Then, the recording data is output through the code conversion unit 12 from the ATIP signal generation point using the count value.

Subsequently, the counter error counter unit 18 counts down the error position value T from the point where the ATIP signal is generated and operates the power control unit 15 from the point where the error position value becomes 0, thereby continuing recording. Perform the mode.

In addition, since a buffer is empty, when a recording error occurs, a playback board is played to reproduce an ATIP signal. Therefore, a position where a recording error occurs is detected. It counts in the part 18.

Then, the recording data is output through the code conversion unit 12 from the ATIP signal generation point using the count value.

Subsequently, the shock error counter unit 18 counts down the error position value T from the point where the ATIP signal is generated, and operates the power control unit 15 from the point where the error position value becomes 0, thereby continuing recording. Perform the mode.

In the optical disc recording / reproducing apparatus and its recording method according to the present invention, if a recording error occurs due to a disturbance such as a shank while recording data on the optical disc, the recording error is corrected and recording is continuously performed from the time when the recording error occurs. Therefore, the utilization efficiency of the optical disc can be improved, and even if a recording error occurs, the error location is quickly found and continuous recording is performed, thereby maximizing convenience in use.

Claims (5)

An apparatus for recording and reproducing data on an optical disc having an ATIP generation unit and a shank detection unit; A code conversion unit for decoding the ATIP signal and the recording data of the ATIP generation unit; A check error counter for outputting a control signal by counting a predetermined time from the ATIP signal decoded by the fraud code converting unit to the generation of the check signal detected by the check detecting unit; And a power control unit for performing a recording mode according to the control signal of the shank error counter unit. An optical disk recording method using a shank error counter section; Initializing the shank error counter to record data on an optical disc; Calculating an error position of the optical disk by a recording error occurring in the optical disk; And recording successively from an error position of the optical disc. The method of claim 2; The calculating step may include: stopping data recording of the optical disc by an empty buffer; Counting and outputting a time from an ATIP signal generation point to a recording stop point of the optical disk; And recording at the recording stop point of the optical disc by applying recording data from the ATIP signal generation point. The method of claim 2; The calculating step may include: stopping data recording of the optical disc by means of a shank; Counting and outputting a time from an ATIP signal generation point to a recording stop point of the optical disk; And recording at the recording stop point of the optical disc by applying recording data from the ATIP signal generation point. The method of claim 2; The calculating step may include: stopping data recording of the optical disc by power off; Counting and outputting a time from an ATIP signal generation point to a recording stop point of the optical disk; And recording at the recording stop point of the optical disc by applying recording data from the ATIP signal generation point.