JP2005302092A - Optical disk reproduction device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical disk reproduction device capable of reproducing reproduction data effectively and correctly even if the synchronization of the address information of the reproduction data on a disk is in disorder. <P>SOLUTION: As opposed to a conventional configuration, the optical disk reproduction device is further provided with a means for halting data reproduction, and configured so as to halt data reproduction once at a predetermined sector and restart the data reproduction from the predetermined sector when an address is shorter than a specified size and a synchronous signal of the address information is abnormal, and to halt the data reproduction once at a predetermined sector and restart the data reproduction from the next sector when the address is longer than a specified size and the synchronous signal of the address information is abnormal. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an optical disk reproducing apparatus, and more particularly to an optical disk reproducing apparatus that can stably reproduce data with a disturbed synchronization signal.

  In a disc in which address information and playback data are different and there is no sync signal in the playback data as in the subcode and main data of a music CD, playback of playback data is started based on the synchronization signal in the address information.

  As a conventional example of an optical disc reproducing apparatus for reproducing an optical disc having an abnormality in a synchronization signal, there is one described in Patent Document 1.

The optical disc playback apparatus described in Patent Document 1 controls a playback signal processing circuit that reads data from an optical disc, an encoder that generates the read data as music data, a fader that converts the music data into silence data, and the entire system. When an optical disk with an abnormal synchronization signal is reproduced, the CPU detects the address of the data of the abnormal part and outputs a muting signal that is zero data for a predetermined time with respect to the output from the encoder Is output, and the abnormal sound generated when the synchronization signal is reproduced in an abnormal part is extinguished.
JP-A-9-153256 (page 7, FIG. 4)

  However, in the above conventional technique, when the synchronization of the address information is disturbed during reproduction of the reproduction data, for example, because the data additional recording position is shifted, the address information can be synchronized based on the synchronization signal after the next sector. However, since the reproduction data corresponding to the address information does not have a synchronization signal, there is a problem that the reproduction data is read out from the optical disk without being out of synchronization.

  The present invention has been made in order to solve the above-described conventional problems, and an optical disc capable of effectively and correctly reproducing the reproduction data even when the synchronization of the address information of the reproduction data on the disc is disturbed. An object is to provide a playback device.

  In order to solve the above-mentioned problem, the present invention comprises means for detecting whether or not the synchronization of address information is disturbed, and means for stopping data reproduction of main data when it is detected that synchronization is disturbed. By performing control so that data reproduction is performed again from a sector in which address information synchronization is normal later, data shift of main data can be prevented even after synchronization is disturbed.

  That is, the optical disk reproducing apparatus according to claim 1 of the present invention detects a synchronization signal of address information and outputs it, and whether or not the detection interval of the address information synchronization signal is shorter than a predetermined interval. An out-of-synchronization detection unit that outputs an instruction signal to stop data reproduction when detected as short, a stop instruction unit that instructs to stop data reproduction in accordance with the instruction signal from the out-of-sync detection unit, and an optical disc reproducing apparatus Control means for performing integrated control of each part of the control signal, the control means, when the data reproduction is stopped based on the instruction signal from the out-of-synchronization detection unit, the synchronization signal detected at an interval shorter than the predetermined interval Is detected again and control is made to resume data reproduction.

  As a result, when it is detected that the address information is out of synchronization, the data reproduction is immediately stopped, and the data reproduction is resumed from the sector where the synchronization of the next address information is normal. Data shift of data can be prevented.

  Also, the optical disk reproducing apparatus according to claim 2 of the present invention detects and outputs a synchronization signal of address information, and generates and outputs a pseudo synchronization signal when the synchronization signal cannot be detected until a predetermined interval. And detecting whether or not the detection interval of the synchronization signal of the address information is longer than a predetermined interval, and if it is detected, outputs an instruction signal for stopping data reproduction and an instruction signal for reproducing data of a predetermined number of sectors A non-synchronization detection unit, a predetermined data processing unit that counts data reproduction of the predetermined number of sectors and outputs an instruction signal to stop data reproduction when the counting is finished, and the non-synchronization detection unit and the predetermined data processing unit A stop instructing unit for instructing to stop data reproduction in accordance with the instruction signal; and a control unit for performing integrated control of each unit of the optical disc reproducing apparatus. When the reproduction is stopped based on the instruction signal from the non-synchronization detection unit, after the data reproduction for the predetermined number of sectors is counted from the data stopped by the predetermined data processing unit, the data reproduction is stopped again, and then the data Control is made so that playback is resumed.

  As a result, when it is detected that the address information is not synchronized, the data reproduction is immediately stopped, the data of the predetermined number of sectors is reproduced, the data reproduction is stopped again, and the data is reproduced from the sector where the synchronization of the address information is normal. By restarting, it is possible to prevent the data shift of the main data even after the synchronization is disturbed.

  An optical disk reproducing apparatus according to a third aspect of the present invention includes: a synchronization detection unit that detects and outputs a synchronization signal of address information and generates and outputs a pseudo synchronization signal when the synchronization signal cannot be detected until a predetermined interval; Detecting whether or not the detection interval of the synchronization signal of the address information is longer than a predetermined interval, and when detecting that it is long, a no-synchronization detecting unit for outputting a signal instructing data reproduction of a predetermined number of sectors; and the predetermined number of sectors A predetermined data processing unit that outputs a data reproduction stop instruction signal when the counting is finished, and a stop instruction unit that instructs the data reproduction stop according to the instruction signal of the predetermined data processing unit, And a control means for performing integrated control of each part of the optical disk playback apparatus, wherein the control means is a playback instruction from the non-synchronization detection section by the predetermined data processing section. Signal the data reproduction of the predetermined sector number of the original after counting, after stopping the data reproduction, it is characterized in that for controlling to restart the data reproduction.

  As a result, when it is detected that the address information is not synchronized, the data reproduction is stopped after the predetermined number of sectors are reproduced, and the synchronization is disturbed by restarting the data reproduction from the sector in which the address information is normally synchronized. Even later, the main data can be prevented from being shifted.

  According to a fourth aspect of the present invention, there is provided an optical disk reproducing device according to the second or third aspect, wherein the predetermined number of sectors of data is one sector.

  Thereby, after the synchronization of the address information is disturbed, it is possible to quickly return to a normal state in which the main data is not shifted.

  In the present invention, there is no synchronization detection means for detecting the absence of address information synchronization, out-of-synchronization detection means for detecting address information out-of-synchronization, and a predetermined instruction for stopping data reproduction after reproducing a predetermined number of sectors of data. Data processing means and stop instruction means for instructing stop of data reproduction are provided, and when synchronization disturbance is detected, data reproduction is stopped and data reproduction is resumed from a sector in which synchronization of address information is normal Therefore, even if the synchronization is disturbed on a disc in which the address information and the reproduction data are different and the reproduction data does not have a synchronization signal, reproduction can be performed while preventing the deviation of the reproduction data.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
Next, Embodiment 1 of the present invention will be described with reference to FIG.
FIG. 1 is a diagram showing a configuration of an optical disc reproducing apparatus according to the first embodiment.

  In FIG. 1, 101 is an optical disk on which data is written, 102 is an optical pickup that reads data written on the optical disk 101, 103 is a servo unit that positions the pickup 102, 104 is a spindle motor that rotates the optical disk 101, 105 A demodulator that demodulates a signal stored in the disk 101 read through the optical pickup 102, and a synchronization detector 106 that detects a synchronization signal from the demodulated data and performs synchronization detection notification and address information notification , 107 determine whether the synchronization signal detected by the synchronization detection unit 106 is detected at an interval shorter than the specified size. If it is determined that the synchronization signal has been detected at a short interval, the data transfer is stopped as out of synchronization. Out-of-synchronization detection unit 108 that instructs the synchronization detection unit 106 The no-synchronization detection unit 109 determines that there is no synchronization when it is determined that the detected synchronization is detected at an interval longer than the specified size. A data transfer unit 110 that transfers the demodulated data to the data buffer unit 112 based on the synchronization timing detected by the next synchronization detection unit 106 after the data transfer activation notification is received from the system controller unit 113. 109 is a stop instruction unit for instructing data transfer to be stopped and 109 is for instructing the system controller 113 to stop data transfer. 111 counts data reproduction of a predetermined number of sectors, and then the stop instruction unit 110 sends data to the data transfer unit 109. The predetermined data processing unit 112 that gives an instruction to stop the transfer is a data for temporarily storing the transferred data. Buffer, 113 is a system controller for controlling the entire system.

  Next, the operation of the optical disk reproducing apparatus configured as described above according to Embodiment 1 of the present invention will be described.

  Here, as shown in FIG. 2, the operation of the apparatus will be described by taking as an example a case where data in which a synchronization signal of address information is detected at an interval Y shorter than a prescribed interval X is reproduced.

  As shown in FIG. 2, when reproducing the data series of addresses N, N + 1, N + 2, N + 3,..., When reproducing data from the address N, the system controller unit 113 first sends the target address N to the servo unit 103. Is instructed to move the optical pickup 102 to the front.

  The data read from the optical disk 101 from before the target address N is demodulated by the demodulator 105, and the demodulated data is transferred to the synchronization detector 106, which detects the synchronization signal 1 from the demodulated data. Then, the synchronization detection notification of the synchronization signal 1 and the address information notification of the currently held address N-1 are sent to the synchronization loss detection unit 107, the synchronization detection unit 108, and the system controller unit 113.

  When the address information notified from the synchronization detection unit 106 matches the address information N−1 immediately before the target address, the system controller unit 113 notifies the data transfer unit 109 of data transfer activation.

  The data transfer unit 109 transfers the reproduction data at the address N to the data buffer unit 112 at the timing when the synchronization signal is detected by the next synchronization detection unit 106.

  Next, the system controller unit 113 instructs the servo unit 103 to move the optical pickup 102 before the target address N + 1.

  The data read from the optical disc 101 from before the target address N + 1 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 2 from the demodulated data. Then, the synchronization detection notification of the synchronization signal 2 and the address information notification of the currently owned address N are sent to the synchronization loss detection unit 107, the synchronization detection unit 108, and the system controller unit 113.

  When the address information notified from the synchronization detection unit 106 matches the address information N immediately before the target address, the system controller unit 113 notifies the data transfer unit 109 of data transfer activation.

  Upon receiving the data transfer activation notification, the data transfer unit 109 transfers the reproduction data of the address N reproduced at the detection timing of the previous synchronization signal 1 to the data buffer unit 112, and also detects the next synchronization signal detection timing. Then, the transfer of the reproduction data at the address N + 1 currently being reproduced is scheduled (data reproduction (1) in FIG. 2).

  Next, the system controller unit 113 instructs the servo unit 103 to move the optical pickup 102 before the target address N + 2, and reproduces data from the address N + 2.

  The data read from the optical disc 101 from before the target address N + 2 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 3 from the demodulated data. Then, the synchronization detection notification of the synchronization signal 3 is sent to the out-of-synchronization detection unit 107, the out-of-synchronization detection unit 108, and the system controller unit 113. However, the synchronization detection timing notified from the synchronization detection unit 106 to the synchronization loss detection unit 107 is shorter than the predetermined size, that is, the synchronization signal 3 is detected earlier than the predetermined size. Suppose that synchronization has been lost, and instructs the stop instruction unit 110 to stop data transfer.

  The stop instruction unit 110 instructs the data transfer unit 109 to stop data transfer to the data buffer unit 112, and notifies the system controller 113 to stop transfer of reproduction data at address N + 1. The data transfer unit 109 stops the transfer of the reproduction data at the address N + 1 to the data buffer unit 112 according to the instruction from the stop instruction unit 110.

  Next, the system controller unit 113 instructs the servo unit 103 to move the optical pickup 102 again before the target address N + 2, and reproduces data from the address N + 2.

  The data read from the optical disc 101 from before the target address N + 2 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 3 from the demodulated data. Then, the synchronization loss detection unit 107, the synchronization detection unit 108, and the system controller unit 113 are notified of the synchronization detection of the synchronization signal 3 and the address information of the currently held address N + 1.

  When the address information notified from the synchronization detection unit 106 matches the address information N + 1 immediately before the target address, the system controller unit 113 notifies the data transfer unit 109 of data transfer activation.

  Upon receiving the data transfer start notification, the data transfer unit 109 transfers the reproduction data at the address N + 1 reproduced at the previous synchronization detection timing to the data buffer unit 112 (data reproduction (2) in FIG. 2).

  As described above, in the optical disc reproducing apparatus according to the first embodiment, the transfer of the reproduction data is stopped when the out-of-synchronization of the address N + 2 is detected, and the data reproduction is resumed from the address N + 2 where the address information is normally synchronized. Thus, the synchronization of the address information and the deviation of the reproduction data due to the synchronization disturbance can be eliminated, and the synchronization of the address information after the address N + 2 and the reproduction data can be returned to the correct correspondence.

(Embodiment 2)
Hereinafter, an optical disk reproducing apparatus according to Embodiment 2 of the present invention will be described.
In the second embodiment, the synchronization detection unit 106 detects and outputs the synchronization signal of the address information, and generates and outputs a pseudo synchronization signal when the synchronization signal cannot be detected until a predetermined interval. 108 determines whether or not the synchronization signal detected by the synchronization detection unit 106 is detected at an interval longer than the specified size. If it is determined that the synchronization signal is detected at a longer interval, the stop instruction unit 110 determines that there is no synchronization. An instruction to stop data transfer and an instruction to reproduce data of a predetermined number of sectors are given to the predetermined data processing unit 111, and the predetermined data processing unit 111 detects the same number of synchronizations as the predetermined number of sectors in response to an instruction from the no-synchronization detection unit 108. After the notification is counted, that is, after the data reproduction of the predetermined number of sectors is counted, the stop instruction unit 110 is instructed to stop the data transfer to the data transfer unit 109. Is Umono. In the second embodiment, the predetermined number of sectors or the predetermined number of synchronization detection notifications is 1.

  Next, as shown in FIG. 3, the operation of the optical disk reproducing apparatus according to the second embodiment is described by taking as an example the case of reproducing data in which the synchronization signal of the address information is detected at the interval Z longer than the specified interval X. Will be explained.

  As shown in FIG. 3, when reproducing data from the address N + 1, the system controller unit 113 first instructs the servo unit 103 to move the optical pickup 102 before the target address N + 1.

  The data read from the optical disc 101 from before the target address N + 1 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 2 from the demodulated data. The synchronization loss notification unit 107, the synchronization detection unit 108, the predetermined data processing unit 111, and the system controller unit 113 are notified of the synchronization detection of the synchronization signal 2 and the address information notification of the address N currently held. I do.

  When the address information notified from the synchronization detection unit 106 matches the address information N immediately before the target address, the system controller unit 113 notifies the data transfer unit 109 of data transfer activation.

  Upon receiving the data transfer activation notification, the data transfer unit 109 notifies the predetermined data processing unit 111 of the data transfer activation, and the data buffer unit displays the reproduction data of the address N reproduced at the detection timing of the previous synchronization signal 1. 112 and schedules the transfer of the reproduction data at the address N + 1 currently being reproduced at the next synchronization signal detection timing (data reproduction (1) in FIG. 3).

  Next, when the synchronization detection timing notified from the synchronization detection unit 106 to the non-synchronization detection unit 108 is longer than the specified size as in the address N + 2 in FIG. The synchronization signal 3 is output, and the synchronization detection notification of the pseudo synchronization signal 3 is currently held in the out-of-sync detection unit 107, the no-synchronization detection unit 108, the predetermined data processing unit 111, and the system controller unit 113. The address information notification of address N + 1 is performed.

  The no-synchronization detecting unit 108 determines that there is no synchronization, instructs the stop instruction unit 110 to stop data transfer, and instructs the predetermined data processing unit 111 to reproduce a predetermined amount of data (step S401 in FIG. 4).

  Here, the system controller unit 113 receives the pseudo synchronization signal and notifies the data transfer unit 109 of data transfer activation, the data transfer unit 109 notifies the predetermined data processing unit 111 of data transfer activation, and the data buffer The reproduction data at address N + 1 is transferred to the unit 112 (step S402 in FIG. 4).

  On the other hand, the stop instructing unit 110 instructs the data transfer unit 109 to stop the data transfer to the data buffer unit 112 and instructs the system controller 113 to transfer the reproduction data of the address N + 1 according to an instruction from the non-synchronization detecting unit 108. Notify stop.

  The data transfer unit 109 stops the transfer of the reproduction data of the address N + 1 to the data buffer unit 112 started at the timing of the pseudo synchronization signal in accordance with the instruction of the stop instruction unit 110.

  The system controller 113 notifies the data transfer unit 109 and the data transfer unit 109 notifies the predetermined data processing unit 111 of the start of data transfer after the non-synchronization detection unit 108 instructs the reproduction of the predetermined data. At the time, the predetermined data processing unit 111 starts counting the synchronization detection notification notified from the synchronization detection unit 106. At this time, the count number is zero.

  Next, the system controller unit 113 instructs the servo unit 103 to move the optical pickup unit 102 before the target address N + 2, and reproduces data from the address N + 2.

  The data read from the optical disc 101 from before the target address N + 2 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 4 from the demodulated data. Then, the synchronization loss detection unit 107, the non-synchronization detection unit 108, and the system controller unit 113 are notified of the synchronization detection of the synchronization signal 4 and the address information of the currently held address N + 1.

  The predetermined data processing unit 111 counts up upon receiving the synchronization detection notification of the synchronization signal 4, and the count number becomes 1 (step S403 in FIG. 4).

  When the address information notified from the synchronization detection unit 106 matches the address information N + 1 immediately before the target address, the system controller unit 113 notifies the data transfer unit 109 of data transfer activation.

  The data transfer unit 109 notifies the predetermined data processing unit 111 of the start of data transfer, and transfers the reproduction data at the address N + 1 reproduced at the detection timing of the previous synchronization signal 3 to the data buffer unit 112 (data in FIG. 3). Playback (2)).

  Next, the system controller unit 113 instructs the servo unit 103 to move the optical pickup unit 102 before the target address N + 3.

  The data read from the optical disc 101 from before the target address N + 3 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 5 from the demodulated data. Then, the synchronization detection notification of the synchronization signal 5 and the address information notification of the currently held address N + 1 are sent to the synchronization loss detection unit 107, the synchronization detection unit 108, and the system controller unit 113.

  The predetermined data processing unit 111 counts up in response to the synchronization detection notification of the synchronization signal 5, and when the count number becomes 2 and exceeds the predetermined number of synchronization notifications, instructs the stop instruction unit 110 to stop data transfer. (Steps S403 to S404 in FIG. 4).

  The stop instruction unit 110 instructs the data transfer unit 109 to stop the transfer of data to the data buffer unit 112 and notifies the system controller 113 to stop the transfer of the reproduction data at the address N + 2. The data transfer unit 109 stops the transfer of the reproduction data at the address N + 2 to the data buffer unit 112.

  Next, the system controller unit 113 instructs the servo unit 103 to move the optical pickup unit 102 again before the target address N + 3.

  The data read from the optical disc 101 from before the target address N + 3 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 5 from the demodulated data. Then, the synchronization detection notification of the synchronization signal 5 and the address information of the address N + 2 currently held are sent to the synchronization loss detection unit 107, the synchronization detection unit 108, and the system controller unit 113.

  When the address information notified from the synchronization detection unit 106 matches the address information N + 2 immediately before the target address, the system controller unit 113 notifies the data transfer unit 109 of data transfer activation.

  The data transfer unit 109 transfers the reproduction data of the address N + 2 reproduced at the detection timing of the previous synchronization signal 4 to the data buffer unit 112 (data reproduction (3) in FIG. 3).

  As described above, the optical disk reproducing apparatus according to the second embodiment receives the pseudo-synchronization signal upon detection of no synchronization of the address N + 2, stops data transfer, and reproduces data for one sector from the address N + 2. Since the data reproduction is resumed from the address N + 3, which is a sector in which the synchronization of the address information is normal after the data reproduction is stopped again, the synchronization of the address information and the deviation of the reproduction data caused by the synchronization disturbance are eliminated, The synchronization of address information after address N + 3 and the reproduction data can be returned to the correct correspondence. In addition, by always stopping the data transfer at the timing of the pseudo synchronization signal, it is possible to reliably reproduce the data series without shifting the data regardless of the state of the next synchronization signal.

(Embodiment 3)
Hereinafter, an optical disk reproducing apparatus according to Embodiment 3 of the present invention will be described.
In the third embodiment, the synchronization detection unit 106 detects and outputs a synchronization signal of address information, and generates and outputs a pseudo synchronization signal when the synchronization signal cannot be detected until a predetermined interval. 108 determines whether or not the synchronization detected by the synchronization detection unit 106 is detected at an interval longer than the specified size. If it is determined that the synchronization is detected at a longer interval, the predetermined data processing unit 111 determines that there is no synchronization. An instruction to reproduce data of a predetermined number of sectors is given. In addition, the predetermined data processing unit 111 counts the same number of synchronization detection notifications as the predetermined number of sectors according to an instruction from the no-sync detection unit 108, that is, counts data reproduction of the predetermined number of sectors, and then sends the data to the stop instruction unit 110. The data transfer unit 109 is instructed to stop data transfer. In the third embodiment, the predetermined number of sectors or the predetermined number of synchronization detection notifications is 1.

  Next, as shown in FIG. 5, the operation of the optical disk reproducing apparatus according to the third embodiment will be described by taking as an example the case where data whose address information synchronization signal is detected at an interval Z longer than the prescribed interval X is reproduced. Will be explained.

  As shown in FIG. 5, when reproducing data from the address N + 1, the system controller unit 113 first instructs the servo unit 103 to move the optical pickup 102 before the target address N + 1.

  The data read from the optical disc 101 from before the target address N + 1 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 2 from the demodulated data. The synchronization detection notification of the synchronization signal 2 and the address information of the address N currently held are sent to the synchronization loss detection unit 107, the no-synchronization detection unit 108, the predetermined data processing unit 111, and the system controller unit 113. Notice.

  When the address information notified from the synchronization detection unit 106 matches the address information N immediately before the target address, the system controller unit 113 notifies the data transfer unit 109 of data transfer activation.

  Upon receiving the data transfer activation notification, the data transfer unit 109 notifies the predetermined data processing unit 111 of the data transfer activation, and the data buffer unit displays the reproduction data of the address N reproduced at the detection timing of the previous synchronization signal 1. 112, and schedules the transfer of the reproduction data at the address N + 1 currently being reproduced at the next synchronization signal detection timing (data reproduction (1) in FIG. 5).

  Next, when the synchronization detection timing notified from the synchronization detection unit 106 to the no-synchronization detection unit 108 is longer than the specified size as in the address N + 2 in FIG. 5, the synchronization detection unit 106 exceeds the specified size. The pseudo-synchronization signal 3 is output, and the out-of-synchronization detection unit 107, the out-of-synchronization detection unit 108, the predetermined data processing unit 111, and the system controller unit 113 are currently in possession of the synchronization detection notification of the pseudo-synchronization signal 3. The address information of the existing address N + 1 is notified.

  The no-synchronization detecting unit 108 determines that there is no synchronization and instructs the predetermined data processing unit 111 to reproduce a predetermined amount of data (step S601 in FIG. 6).

  The predetermined data processing unit 111 counts the synchronization detection notification notified from the synchronization detection unit 106 after the data reproduction of the predetermined number of sectors from the no-synchronization detection unit 108 is notified. At this time, the count number is zero.

  When the system controller 113 receives the pseudo-synchronization signal 3 and the address information notified from the synchronization detection unit 106 matches the address information N + 1 immediately before the target address, the system controller 113 notifies the data transfer unit 109 of data transfer activation. Then, the data transfer unit 109 transfers the reproduction data of the address N + 1 reproduced at the detection timing of the previous synchronization signal 2.

  Next, the system controller unit 113 instructs the servo unit 103 to move the optical pickup unit 102 before the target address N + 2.

  The data read from the optical disc 101 from before the target address N + 2 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 4 from the demodulated data. Then, the synchronization loss detection unit 107, the non-synchronization detection unit 108, and the system controller unit 113 are notified of the synchronization detection of the synchronization signal 4 and the address information of the currently held address N + 1.

  The predetermined data processing unit 111 counts up upon receiving the synchronization detection notification of the synchronization signal 4, and the count number becomes 1 (step S602 in FIG. 6).

  Next, the system controller unit 113 instructs the servo unit 103 to move the optical pickup unit 102 before the target address N + 3.

  The data read from the optical disc 101 from before the target address N + 3 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 5 from the demodulated data. Then, the synchronization detection notification of the synchronization signal 5 and the address information of the address N + 2 currently held are sent to the synchronization loss detection unit 107, the synchronization detection unit 108, and the system controller unit 113.

  The predetermined data processing unit 111 counts up upon receiving the synchronization detection notification of the synchronization signal 4, and when the count number becomes 2 and the predetermined number of synchronization detection notifications is reached, the stop instruction unit 110 is instructed to stop data transfer. (Steps S602 to S604 in FIG. 6).

  The stop instruction unit 110 instructs the data transfer unit 109 to stop data transfer to the data buffer unit 112 and notifies the system controller 113 to stop transfer of reproduction data at address N + 2. The data transfer unit 109 stops the transfer of the reproduction data at the address N + 2 to the data buffer unit 112.

  Next, the system controller unit 113 instructs the servo unit 103 to move the optical pickup unit 102 again before the target address N + 3.

  The data read from the optical disc 101 from before the target address N + 3 is demodulated by the demodulator 105, and the demodulated data is transferred to the sync detector 106. The sync detector 106 detects the sync signal 5 from the demodulated data. Then, the synchronization detection notification of the synchronization signal 5 and the address information of the address N + 2 currently held are sent to the synchronization loss detection unit 107, the synchronization detection unit 108, and the system controller unit 113.

  When the address information notified from the synchronization detection unit 106 matches the address information N + 2 immediately before the target address, the system controller unit 113 notifies the data transfer unit 109 of data transfer activation.

  The data transfer unit 109 transfers the reproduction data at the address N + 2 reproduced at the detection timing of the previous synchronization signal 4 to the data buffer unit 112 (data reproduction (2) in FIG. 5).

  As described above, in the optical disk reproducing apparatus according to the third embodiment, when the pseudo-synchronization signal output in response to the detection of no synchronization at the address N + 2 is received, the data reproduction is stopped after continuing to reproduce the data of one sector, Then, by resuming data reproduction from address N + 3, which is a sector in which address information is normally synchronized, address information synchronization and reproduction data deviation due to synchronization disturbance are eliminated, and address information after address N + 3 is synchronized and reproduced. Data can be returned to the correct correspondence. In particular, when the synchronization signal that follows the pseudo-synchronization signal is normal, the data reproduction can be stopped only once and the synchronization of the address information and the data shift can be prevented.

  The disc reproducing apparatus according to the present invention has an effect that data reproduction can be performed on disc data whose synchronization is disturbed without being out of sync with the data. It is useful as an optical disk reproducing apparatus that can be improved.

It is a block diagram which shows the structure of the optical disk reproducing | regenerating apparatus by Embodiment 1 thru | or Embodiment 3 of this invention. It is a figure which shows the data example containing the sector shorter than a regulation value in Embodiment 1 of this invention, and the mode of the reproduction | regeneration. It is a figure which shows the data example containing the sector longer than a regulation value in Embodiment 2 of this invention, and the mode of the reproduction | regeneration. It is an operation | movement flowchart of the predetermined data processing part in Embodiment 2 of this invention. It is a figure which shows the example of data including the sector longer than a regulation value in Embodiment 3 of this invention, and the mode of the reproduction | regeneration. It is an operation | movement flowchart of the predetermined data processing part in Embodiment 3 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 101 Optical disk 102 Optical pick-up part 103 Servo part 104 Spindle motor part 105 Demodulation part 106 Synchronization detection part 107 Out-of-synchronization detection part 108 No-synchronization detection part 109 Data transfer part 110 Stop instruction part 111 Predetermined data processing part 112 Data buffer part 113 System controller Part

Claims (4)

A synchronization detector for detecting and outputting a synchronization signal of address information;
Detecting whether or not the detection interval of the synchronization signal of the address information is shorter than a predetermined interval, and detecting that it is short, the out-of-synchronization detection unit that outputs an instruction signal to stop data reproduction;
In accordance with the instruction signal of the out-of-sync detection unit, a stop instruction unit that instructs to stop data reproduction,
Control means for performing integrated control of each part of the optical disk playback device,
When the data reproduction is stopped based on an instruction signal from the out-of-synchronization detection unit, the control unit performs control so that the synchronization signal detected at an interval shorter than the predetermined interval is detected again and the data reproduction is resumed. ,
Optical disc reproducing apparatus A synchronization detection unit that detects and outputs a synchronization signal of address information and generates and outputs a pseudo synchronization signal when the synchronization signal cannot be detected until a predetermined interval;
It is detected whether the detection interval of the synchronization signal of the address information is longer than a predetermined interval, and when it is detected, detection of no synchronization is performed to output an instruction signal for stopping data reproduction and an instruction signal for reproducing data of a predetermined number of sectors And
A predetermined data processing unit that counts data reproduction of the predetermined number of sectors and outputs an instruction signal to stop data reproduction when the counting is finished;
According to the instruction signal of the non-synchronization detection unit and the predetermined data processing unit, a stop instruction unit for instructing stop of data reproduction,
Control means for performing integrated control of each part of the optical disk playback device,
When the data reproduction is stopped based on the instruction signal from the non-synchronization detecting unit, the control unit counts the data reproduction for the predetermined number of sectors from the data stopped by the predetermined data processing unit, and then performs the data reproduction again. Control to resume data playback after stopping,
An optical disk reproducing apparatus characterized by the above. A synchronization detection unit that detects and outputs a synchronization signal of address information and generates and outputs a pseudo synchronization signal when the synchronization signal cannot be detected until a predetermined interval;
Detecting whether or not the detection interval of the synchronization signal of the address information is longer than a predetermined interval, and if not detected, a no-synchronization detector that outputs a signal instructing data reproduction of a predetermined number of sectors;
A predetermined data processing unit that counts data reproduction of the predetermined number of sectors and outputs an instruction signal to stop data reproduction when the counting is finished;
In accordance with an instruction signal from the predetermined data processing unit, a stop instruction unit that instructs to stop data reproduction,
Control means for performing integrated control of each part of the optical disk playback device,
The control means counts the data reproduction for the predetermined number of sectors based on the reproduction instruction signal from the non-synchronization detecting unit by the predetermined data processing unit, stops the data reproduction, and then restarts the data reproduction. To control,
An optical disk reproducing apparatus characterized by the above. In the optical disc reproducing apparatus according to claim 2 or 3,
The data of the predetermined number of sectors is one sector.
An optical disk reproducing apparatus characterized by the above.

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