JP4019532B2 - Information processing device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The invention described in the claims of the present application reads digital information data recorded on a recording medium on which digital information data such as audio information data is recorded under a selected reproduction mode state. The present invention relates to an information processing apparatus for reproducing information represented by the information processing apparatus.
[0002]
[Prior art]
A composite signal including a video signal such as a television signal and an audio signal is converted into digital data, and an inclined recording track inclined with respect to the longitudinal direction is formed on a magnetic tape and recorded. A composite signal including a video signal and an audio signal converted into digital data from a magnetic tape on which a tilted recording track is formed and recorded. A so-called digital video tape recorder (digital VTR) that reads and analogizes and obtains a playback video signal and a playback audio signal combines recording and playback of a composite signal including a video signal and an audio signal using a magnetic tape. Proposed as something that can be done without substantially reducing the quality of the signal. There. For such a digital VTR, a description regarding examples thereof can be found in, for example, a document published by Nikkei BP: “Nikkei Electronics (Nikkei Electronics)”, 10-11 1993 (No. 592), pages 115-122. Can see.
[0003]
Even in the case of such a digital VTR, for example, a signal section (one frame of the composite signal) corresponding to each frame of the video signal included in the composite signal is a recording section. An example of the relationship between the recording mode and the recording mode on the magnetic tape on which it is recorded is as shown in FIG. In the example shown in FIG. 3, one frame of digital composite data obtained by subjecting one frame of the composite signal to analog / digital conversion (A / D conversion) is sequentially arranged on the magnetic tape TP. The information is distributed and recorded on 10 adjacent ones of the inclined recording tracks TK. Such recording is performed by rotating the magnetic tape TP with a rotating magnetic head to which digital composite data for one frame is sequentially supplied. The arrows DY and DH in FIG. 3 indicate the traveling direction of the magnetic tape TP, respectively. The scanning direction of the rotating magnetic head with respect to the magnetic tape TP is shown.
[0004]
Each of a large number of inclined recording tracks TK arranged on the magnetic tape TP represents a data structure in the inclined recording track TK from the starting end side to the ending side, and a reference for position in data editing or the like. Area IT in which data to be recorded is recorded, area AD in which audio information data representing the contents of the two-channel audio signal of the stereo left signal and stereo right signal in the composite signal is recorded, and the content of the video signal in the composite signal An area VD in which video information data representing the time information is recorded and an area SC in which time code data representing the time information are recorded are formed.
[0005]
For example, the audio information data recorded in the area AD in one inclined recording track TK has a data synchronization block portion as a main portion, and a preamble portion and a postamble portion are arranged before and after the data synchronization block portion, respectively. The data synchronization block part constituting the main part conforms to a coding format as shown in FIG. 4, for example. This coding format includes 14 data synchronization blocks whose synchronization block number i is 2 to 15, and each data synchronization block is formed of 90 bytes whose byte position number j is 0 to 89. Has been.
[0006]
In each of the nine data synchronization blocks whose synchronization block number i is 2 to 10, the first 2 bytes (byte position number j is 0 and 1) are used as synchronization data, and the next 3 bytes (byte position number). j is 2 to 4) is the ID code, the next 5 bytes (byte position number j is 5 to 9) is the audio auxiliary data, and the subsequent 72 bytes (byte position number j is 10 to 81). The audio data is based on one of the two-channel audio signals of the stereo left signal and the stereo right signal, which is the main information data, and the audio data has an inner 8 bytes (byte position number j is 82 to 89). Parity is added. The ID code provides track pair information corresponding to the numbers of the two adjacent oblique recording tracks, head azimuth information relating to the head azimuth relating to the rotating magnetic head relating to each oblique recording track, information relating to the synchronization block number i, etc. In addition, the audio auxiliary data provides information regarding the recording condition of the audio data including the number of constituent bits. These ID code and audio auxiliary data are attached information data added to audio data which is main information data, including synchronization data.
[0007]
The audio data in each of the nine data synchronization blocks whose synchronization block number i is 2 to 10 (audio data whose synchronization block number i is 2 to 10) has synchronization block numbers i and 2 in FIG. As illustrated, it is assumed to include 36 data segments each composed of 2 bytes. As shown in FIG. 4, these data segments are originally from the first one in the data synchronization block whose synchronization block number i is 2 to the last one in the data synchronization block whose synchronization block number i is 10, For example, it appears with consecutive segment numbers D0 to D323.
[0008]
However, the audio information data actually recorded in the area AD in each inclined recording track TK is included in, for example, one frame of digital composite data distributed and recorded in 10 inclined recording tracks TK. Interleave processing is performed on a large number of data segments in order to reduce code errors in units of audio data in the entire audio information data (audio information data for one frame). Accordingly, in the audio data included in the audio information data recorded in the area AD in one inclined recording track TK, 36 pieces of data constituting each of the audio data having the synchronization block number i of 2 to 10 It is assumed that the segments are not arranged in the order of the segment numbers but are arranged in accordance with the interleaving process.
[0009]
Each of the five data synchronization blocks having the synchronization block number i of 11 to 15 has the first 2 bytes (byte position number j is 0 and 1) as synchronization data, and the next 3 bytes (bytes). Position number j is 2 to 4) is an ID code, the subsequent 77 bytes (byte position number j is 5 to 81) is outer parity, and the outer parity is 8 bytes (byte position number j is 82 to 89). The inner parity is added. Therefore, the audio data exists in a range indicated by hatching in FIG. 4 where the synchronization block number i is 2 to 10 and the byte position number j is 10 to 81.
[0010]
Under such circumstances, a digital VTR includes audio information data recorded in the area AD by the rotating magnetic head from each of the inclined recording tracks TK formed in a large number on the magnetic tape TP as described above. When the composite data is read to obtain a playback video signal and a 2-channel playback audio signal based on the digital composite data, in addition to performing a code error correction process on the audio information data when playing back the 2-channel audio signal. Thus, it is necessary to perform deinterleaving processing for a large number of data segments subjected to interleaving processing that constitute audio data based on two-channel audio signals included in the audio information data.
[0011]
The interleaving process for audio data based on the two-channel audio signal included in the audio information data recorded in the area AD in each inclined recording track TK is, for example, distributed and recorded in 10 inclined recording tracks TK. It is applied in units of audio data in the entire audio information data for a frame. Accordingly, deinterleaving processing for a large number of data segments that have been subjected to interleaving processing that constitutes audio data based on two-channel audio signals is also performed, for example, for one frame of audio information read from ten inclined recording tracks TK. This is performed in units of audio data in the data.
[0012]
In the deinterleaving process for a large number of data segments subjected to the interleaving process constituting the audio data, for example, according to the digital data processing apparatus disclosed in Japanese Patent Laid-Open No. 9-282804, the audio data Is prepared, a write address for the audio data in the data memory means is controlled, and a plurality of data segments in which audio data for one frame is subjected to interleaving processing constituting it Is stored in the data memory means in a state where the deinterleaving process is performed on the data, and then the read address for the audio data in the data memory means is controlled, and the data memory means stores the 1 stored in it. O for frame Audio data is to de-interleaving processing for a plurality of data segments are read in a state which has been subjected.
[0013]
In such a deinterleaving process, the track number, which is the number in the 10 inclined recording tracks TK from which one frame of audio information data for each inclined recording track TK is read, is detected. Based on the audio information data read from the inclined recording track TK on the tape TP, the byte data whose order is indicated by the byte position number is counted, the synchronization block number is detected, and the like. Then, the count result for the byte data, the detected synchronization block number, the detected track number, etc. are used for forming a write address control signal for controlling the write address for the audio data in the data memory means.
[0014]
[Problems to be solved by the invention]
As described above, in the digital VTR, the operation of reading the digital composite data from the inclined recording tracks TK formed in a large number on the magnetic tape TP by the rotating magnetic head is selected from several different playback mode states. In the playback mode state. As such a reproduction mode state, a normal reproduction mode state in which the traveling speed of the magnetic tape TP is the same as the traveling speed of the magnetic tape TP at the time of recording, and the traveling speed of the magnetic tape TP is the same as that of the magnetic tape TP at the time of recording. A variable speed playback mode state (JOG playback mode state) that is slower than the traveling speed, for example, a 1/10 speed playback mode state in which the traveling speed of the magnetic tape TP is 1/10 of the traveling speed of the magnetic tape TP during recording, Generally, a still reproduction mode state in which the same digital composite data for one frame is repeatedly read from the magnetic tape TP is prepared.
[0015]
When the digital composite data is read from the inclined recording track TK formed in a large number on the magnetic tape TP by the rotating magnetic head under the still reproduction mode, the same digital composite data for one frame is read from the magnetic tape TP. Are repeatedly read, and each of the video information data (one frame of video information data) and one frame of audio information data included in the read digital composite data for one frame is repeatedly obtained. . A still image can be obtained by performing image reproduction using a reproduced video signal based on video information data for one frame obtained repeatedly. At this time, audio information for one frame obtained repeatedly is obtained. When voice playback is performed using a playback audio signal based on data, the same voice is repeatedly generated.
[0016]
Therefore, when digital composite data is read from the inclined recording track TK formed in a large number on the magnetic tape TP by the rotating magnetic head under the still reproduction mode state, for example, the rotating magnetic head A deinterleave processing unit that performs a deinterleave process on audio data based on a two-channel audio signal included in audio information data obtained based on digital composite data read from the magnetic tape by the The playback audio signal is not obtained.
[0017]
However, when the digital composite data is read from the inclined recording track TK formed in a large number on the magnetic tape TP by the rotating magnetic head under the still reproduction mode state, the two channels included in the audio information data are read. When the deinterleave processing unit that performs deinterleave processing on the audio data based on the audio signal is put into a non-operating state, a large number of arrays are formed on the magnetic tape TP by the rotating magnetic head under the still reproduction mode state. From the first state in which the digital composite data is read from the inclined recording track TK, the magnetic tape is rotated by the rotating magnetic head under a playback mode state other than the still playback mode state, for example, the normal playback mode state or the JOG playback mode state. Many sequences in TP When the transition to the second state in which the digital composite data is read from the formed inclined recording track TK, the sound reproduction to be performed is not performed during the predetermined period at the beginning of the second state. There is a problem.
[0018]
That is, when the transition from the first state to the second state occurs, the tape drive operation for causing the magnetic tape TP to run at a running speed corresponding to, for example, the normal reproduction mode state or the JOG reproduction mode state is performed. A predetermined time is required until the normal playback mode state or the JOG playback mode state is stabilized. In addition, in the audio information data obtained based on the digital composite data read from the magnetic tape by the rotating magnetic head by the deinterleave processing unit, the deinterleave processing unit that has been inactive until then is set in the operating state. An operation for performing deinterleaving processing on audio data based on the two-channel audio signal is started. For example, in the period until the normal playback mode state or the JOG playback mode state is stabilized, the deinterleaving processing is performed. The audio data that has been subjected to deinterleaving processing by the unit does not represent a two-channel audio signal with an appropriate phase relationship, and as a result, the stereo left signal and the stereo right signal having the appropriate phase relationship Channel playback audio Oh signal is not obtained.
[0019]
The audio data that has been subjected to the deinterleave processing by the deinterleave processing unit does not represent a two-channel audio signal with an appropriate phase relationship, and a stereo left signal and a stereo right signal that have an appropriate phase relationship. If the two-channel playback audio signal cannot be obtained, deinterleaving processing by the deinterleave processing unit has been performed so that undesired sound playback by the playback audio signal is not performed. The muting state for the audio data or the reproduced audio signal based on the audio data is taken. As a result, immediately after the transition from the first state to the second state occurs, a relatively long silence period is generated due to the muting state being taken.
[0020]
In view of such a point, the invention described in the claims of the present application can perform interleaving processing such as audio information data including audio data representing a plurality of channels of audio signals subjected to interleaving processing. The digital information data recorded thereon is read from the recording medium on which the digital information data including information data representing the information signals of the plurality of channels is applied, and the interleaved information data is decoded. In obtaining the output information data representing the information signal of a plurality of channels based on the information data subjected to the interleaving processing, the first and second data processing units are not operating normally. Recording medium by head unit under specific playback mode state Even when the digital information data is read and the first and second data processing units shift to a state in which they normally operate, after the shift, the muting state for the output information data or the reproduction information signal based thereon is changed. The present invention proposes an information processing apparatus that can immediately obtain output information data representing information signals of a plurality of channels based on information data subjected to deinterleave processing without being taken.
[0021]
[Means for Solving the Problems]
The information processing apparatus according to the invention described in claim 1 or claim 2 in the claims of the present application is composed of a plurality of data segments subjected to interleaving processing in units of predetermined data sections, and includes a plurality of channels. A head unit for reading the digital information data under a selected reproduction mode state from a recording medium on which digital information data formed by adding auxiliary information data to main information data representing the information signal is recorded. The main information data in the digital information data obtained from the above is subjected to deinterleaving processing and predetermined digital processing for a plurality of interleaved data segments, so that the information signals of the plurality of channels are reproduced with an appropriate phase relationship. First to obtain the first output information data to be The main information data in the digital information data obtained from the data processing unit and the head unit is subjected to deinterleaving processing and predetermined digital processing for a plurality of data segments subjected to interleaving processing, and second output information data is obtained. A second data processing unit to be obtained, a data selection unit for selectively extracting the first output information data and the second output information data, and an operation control unit for the data selection unit. When reading of digital information data from the recording medium by the recording unit is started under a specific reproduction mode state, the data selection unit is first brought into a state of taking out the second output information data, and then the specific reproduction mode state When stabilization is achieved, the data selection unit is assumed to shift to a state in which the first output information data is extracted. It is.
[0022]
The information processing apparatus according to the invention described in claim 3 or claim 4 in the claims of the present application includes a plurality of pieces of video information data and a plurality of pieces of data subjected to interleaving processing in units of predetermined data sections. Audio information data composed of segments and having audio data added to audio data representing audio signals of a plurality of channels, and video information data and audio information data selected from a recording medium in a playback mode state. A multi-channel audio signal is obtained by performing de-interleaving processing and predetermined digital processing on a plurality of data segments that have been subjected to interleaving processing on audio data in an audio information data obtained from the head portion to be originally read and the head portion. Each is the right phase A first data processing unit that obtains first output audio data to be reproduced in association with the audio data in the audio information data obtained from the head unit, and a plurality of data segments that have been subjected to interleaving processing. A second data processing unit that obtains second output audio data by performing interleaving and predetermined digital data processing; and a data selection unit that selectively extracts the first output audio data and the second output audio data And an operation control unit for the data selection unit, wherein the operation control unit reads the video information data and the audio information data from the recording medium by the head unit based on the video information data read from the recording medium. Will be played from the still playback mode. When starting under a playback mode state different from the still playback mode state, first, the data selection unit is brought into a state of taking out the second output audio data, and then in a playback mode state different from the still playback mode state. When stabilization is achieved, the data selection unit is shifted to a state of taking out the first output audio data.
[0023]
In the information processing apparatus according to the first or second aspect of the present invention configured as described above, the reading of the digital information data from the recording medium by the head unit is specified. When the playback mode state is started, the operation control unit first performs interleaving processing on the main information data in the digital information data obtained from the head unit in the second data processing unit by the data selection unit. The second output information data obtained by performing the deinterleaving process and the predetermined digital process for the plurality of data segments that have been applied is brought into a state in which it is taken out, and then the specific playback mode state is stabilized. When the data selection unit receives the main information data in the digital information data obtained from the head unit, Obtained by performing deinterleaving processing and predetermined digital processing on a plurality of data segments that have been subjected to squeezing processing, so that each of the information signals of the plurality of channels is reproduced with an appropriate phase relationship. The state is switched to the state where the first output information data from the first data processing unit is taken out.
[0024]
Therefore, for example, the digital information data is read from the recording medium by the head unit under the specific reproduction mode state from the state where the first and second data processing units are not normally operated, and the first Even in the case where the second data processing unit shifts to a state in which the second data processing unit normally operates, after the shift, each of the information signals of the plurality of channels from the first data processing unit is reproduced with an appropriate phase relationship. Until the first output information data is obtained, the second output information data from the second data processing unit is obtained. Therefore, the muting state for the output information data or the reproduction information signal based thereon is obtained. Output information data representing information signals of multiple channels based on the deinterleaved information data can be obtained immediately. It will be.
[0025]
In the information processing apparatus according to the third or fourth aspect of the present invention, the reading of the video information data and the audio information data from the recording medium by the head unit is still possible. When starting under a playback mode state that is different from the still playback mode state shifted from the playback mode state, for example, a normal playback mode state or a JOG playback mode state, the operation control unit first sets the The second data processing unit is obtained by subjecting audio data in the audio information data obtained from the head unit to deinterleaving processing and predetermined digital processing for a plurality of data segments subjected to interleaving processing. The output audio data is ready to be retrieved. When the playback mode state different from the still playback mode state, for example, normal playback mode state or JOG playback mode state is stabilized, the data selection unit converts the audio data in the audio information data obtained from the head unit to The deinterleaving process and the predetermined digital process are performed on the plurality of data segments that have been subjected to the interleaving process, and each of the audio signals of the plurality of channels is obtained as being reproduced with an appropriate phase relationship. The first output audio data from one data processing unit is switched to a state of taking out.
[0026]
Therefore, for example, the video information data and the audio information data are read from the recording medium by the head unit in the still reproduction mode state, and the first and second data processing units are not operating properly. The video information data and the audio information data are read from the recording medium by the head unit under a playback mode state different from the still playback mode state, for example, a normal playback mode state or a JOG playback mode state. Even in the case where the second data processing unit shifts to a state in which the second data processing unit normally operates, after the transition, each of the audio signals of the plurality of channels from the first data processing unit is reproduced with an appropriate phase relationship. The second output audio from the second data processing unit until the first output audio data is obtained. Therefore, the muting state is not taken for the output audio data or the reproduced audio signal of a plurality of channels based on the output audio data, and the channels of the plurality of channels based on the audio data subjected to the deinterleave processing are immediately performed. Output audio data representing an audio signal can be obtained.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows an example of an information processing apparatus according to the invention described in any one of claims 1 to 4 in the claims of the present application, which constitutes a main part of a digital VTR. A digital VTR having a main part constituted by the example shown in FIG. 1 has video information data corresponding to a video signal and audio corresponding to, for example, a two-channel audio signal of a stereo left signal and a stereo right signal. The digital composite data is read from the recording medium on which the digital composite data including the information data is recorded. Based on the video information data and the audio information data included in the read digital composite data, the video signal and the stereo left An operation for reproducing a signal and a two-channel audio signal which is a stereo right signal is performed, and is used with a magnetic tape TP in which inclined recording tracks TK are arranged as shown in FIG.
[0028]
In the example shown in FIG. 1, a magnetic tape drive unit 20 and a read rotary magnetic head unit 21 are provided. The magnetic tape drive unit 20 operates in response to a drive control signal DTP from the operation control unit 10 formed using, for example, a microcomputer, and the inclined recording tracks TK are formed as shown in FIG. The magnetic tape TP thus driven is driven to run at a running speed indicated by the drive control signal DTP. The reading rotary magnetic head unit 21 operates in response to the drive control signal DHD from the operation control unit 10 to rotate and drive the reading rotary magnetic head provided therein. The magnetic tape TP is scanned.
[0029]
The read rotary magnetic head unit 21 includes, for example, four read rotary magnetic heads. These four reading rotary magnetic heads are formed of a large number of inclined recording tracks TK arranged on the magnetic tape TP as indicated by reference numerals 21a, 21b, 21c and 21d in FIG. The four adjacent lines are sequentially scanned, and the digital composite data recorded on the four inclined recording tracks TK is read. An arrow DH in FIG. 2 indicates the scanning direction of each of the read rotary magnetic heads 21a, 21b, 21c and 21d with respect to the inclined recording track TK.
[0030]
Each of the read rotary magnetic heads 21a to 21d has a head azimuth corresponding to the head azimuth of the rotary magnetic head at the time of recording on the inclined recording track TK from which the digital composite data is read. Is the head azimuth for the rotating magnetic head associated with each inclined recording track TK. The reading rotary magnetic heads 21a to 21d read two pieces of digital composite data from two inclined recording tracks TK adjacent to each other, that is, the reading rotary magnetic head 21a and the reading rotary magnetic head 21b. The rotary magnetic head 21b and the read rotary magnetic head 21c, and the read rotary magnetic head 21c and the read rotary magnetic head 21d have different head azimuths.
[0031]
From the read rotary magnetic head unit 21, digital composite data DT read from the inclined recording track TK on the magnetic tape TP is obtained by each of the read rotary magnetic heads 21a to 21d. The digital composite data DT includes video information data corresponding to a video signal, audio information data corresponding to a two-channel audio signal, and other data. The audio information data conforms to a coding format as shown in FIG. 4 and represents audio data representing the contents of the two-channel audio signal as main information data, and additional information added to the audio data. The data includes synchronization data, ID code, audio auxiliary data, and other data. The audio data is an array of a number of data segments that have been interleaved in units of one frame. It is configured.
[0032]
The digital composite data DT obtained from the read rotary magnetic head unit 21 is amplified by the reproduction amplification unit 22 and supplied to the data rearrangement unit 24 through the equalizer unit 23. In the data rearrangement unit 24, the digital composite data DT is recorded as one frame of video information data recorded on the magnetic tape TP in a sequence of 10 inclined recording tracks TK and one frame accompanying it. The digital data DF representing the audio information data is rearranged to form sequentially. The digital data DF obtained from the data rearrangement unit 24 is supplied to the coding unit 25 and subjected to the coding necessary to form independent data of one channel to be the coded digital data DC. The error correction / time axis correction unit 26 is supplied.
[0033]
In the error correction / time axis correction unit 26, error correction processing for code errors detected by inner parity and outer parity included in each of the video information data and the audio information data included in the coded digital data DC. In addition, time axis correction is performed, and video information data and audio information data are separated. The error correction / time axis correction unit 26 derives the video information data DV subjected to the error correction process and the time axis correction, and the audio information data DA subjected to the error correction process.
[0034]
The video information data DV obtained from the error correction / time axis correction unit 26 is supplied to a video information data processing unit (not shown in FIG. 1), and a reproduced video signal based on the video information data DV is formed. On the other hand, the audio information data DA obtained from the error correction / time axis correction unit 26 is supplied to the main deinterleave processing unit 27 and the sub deinterleave processing unit 28, and further supplied to the operation control unit 10.
[0035]
In the main deinterleave processing unit 27, the audio information data DA obtained from the error correction / time axis correction unit 26 is supplied to, for example, a data memory unit 30 formed by a random access memory (RAM). It is supplied to each of the byte count unit 31, the synchronization block number detection unit 32, and the track number detection unit 33.
[0036]
The data memory unit 30 is supplied with a write enable signal CEN from the operation control unit 10. For example, when the write enable signal CEN is at a low level, the data memory unit 30 can write data, and when the write enable signal CEN is at a high level, data writing is disabled.
[0037]
The byte count unit 31 counts each piece of byte data whose rank is indicated by the synchronization block number i and the byte position number j in the audio information data DA. When the byte data is included in the audio data in the audio information data DA, each of a number of data segments constituting the audio data is formed by 2 bytes represented by two byte position numbers j. Yes. Therefore, for example, the count value for the byte data in each data synchronization block represents the arrangement position of each of a number of data segments constituting the audio data. The byte count unit 31 obtains a byte count output signal SBC that represents the count result for the byte data.
[0038]
Further, the synchronization block number detection unit 32 detects the synchronization block number i represented by the ID code in the audio information data DA, and obtains the synchronization block number detection output signal SSD representing the detected synchronization block number i.
[0039]
Further, the track number detection unit 33 obtains a track pair number represented by the track pair information included in the ID code in the audio information data DA and a head azimuth represented by the head azimuth information included in the ID code in the audio information data DA. Further, the inclined recording track including the inclined recording track TK from which the audio information data DA supplied to the main deinterleave processing unit 27 is read based on the obtained track pair number and head azimuth. A track number, which is a number within one frame of TK, is detected, and a track number detection output signal SDT representing the detected track number is obtained.
[0040]
The track pair number indicated by the track pair information is the two adjacent inclined recording tracks TK on the magnetic tape TP including the inclined recording track TK from which the audio information data DA supplied to the main deinterleave processing unit 27 is read. Is a number in one frame of the tilt recording track TK including them. The head azimuth represented by the head azimuth information is a head azimuth for the rotating magnetic head related to the inclined recording track TK from which the audio information data DA supplied to the main deinterleave processing unit 27 has been read.
[0041]
In this way, the byte count output signal SBC obtained from the byte count unit 31, the synchronization block number detection output signal SSD obtained from the synchronization block number detection unit 32, and the track number detection output signal obtained from the track number detection unit 33. The SDT is supplied to the write address signal forming unit 34. In the write address signal forming unit 34, the count result for the byte data represented by the byte count output signal SBC, the synchronization block number represented by the synchronization block number detection output signal SSD, and the track number represented by the track number detection output signal SDT are displayed. Based on this, the arrangement position to be taken when the deinterleaving process is performed for each of the plurality of data segments subjected to the interleaving constituting the audio data in the audio information data DA is calculated. Further, in the write address signal forming unit 34, a write address control signal CW corresponding to the calculated arrangement position is formed, and the write address control signal CW is transmitted to the data memory unit. 30.
[0042]
Accordingly, in the data memory unit 30, the audio data in the audio information data DA supplied from the error correction / time axis correction unit 26 is configured with the write enable signal CEN being at a low level. A plurality of data segments that have been interleaved in units of frames are written by performing write address control according to the write address control signal CW. As a result, the audio data, which is the main information data in the audio information data DA, is in a state where the deinterleaving process has been performed on the plurality of data segments that have been subjected to the interleaving process, and is stored in the data memory unit 30. Will be stored. The write address signal forming unit 34 that supplies the write address control signal CW to the data memory unit 30 forms a write control unit for the data memory unit 30.
[0043]
In this case, the byte count output signal SBC, the synchronization block number detection output signal SSD, and the track number detection output signal SDT, the audio information data DA supplied to the main deinterleave processing unit 27 constitutes the main part of the digital VTR. The example shown in FIG. 1 is obtained when the traveling speed of the magnetic tape TP is obtained in a normal reproduction mode state in which the traveling speed of the magnetic tape TP is the same as the traveling speed of the magnetic tape TP, and the traveling speed of the magnetic tape TP. Is obtained in a JOG playback mode state in which the recording speed is slower than the traveling speed of the magnetic tape TP at the time of recording, for example, in a 1 / 10-speed playback mode state, the byte count unit 31 and the synchronization block, respectively. It is appropriately obtained from the number detection unit 32 and the track number detection unit 33. Therefore, when the write address control signal CW is formed, the count result for the byte data represented by the byte count output signal SBC, the synchronization block number represented by the synchronization block number detection output signal SSD, and the track number detection output signal SDT are represented. The calculation of the array position to be taken when the deinterleaving process is performed for each of the plurality of interleaved data segments constituting the audio data in the audio information data DA performed based on the track number is as follows. The audio information data DA supplied to the deinterleave processing unit 27 is obtained when the example shown in FIG. 1 constituting the main part of the digital VTR is obtained in the normal playback operation mode state and in the JOG playback mode state. Obtained under In any case, it will be properly performed.
[0044]
In the main deinterleave processing unit 27, the clock signal CP from the operation control unit 10 is supplied to each of the clock count unit 35 and the clock count unit 36. The clock count unit 35 and the clock count unit 36 are supplied with the first frame pulse signal CFPL and the second frame pulse signal CFPR from the operation control unit 10, respectively. The first and second frame pulse signals CFPL and CFPR are two-channel audio signals represented by audio data in the audio information data DA obtained from the error correction / time axis correction unit 26, that is, a stereo left signal and a stereo right signal. Is obtained from the operation control unit 10 to guarantee the proper phase.
[0045]
In the clock count unit 35, only when the first frame pulse signal CFPL is supplied from the operation control unit 10, the clock signal CP is counted in synchronization with the first frame pulse signal CFPL. Count output data DCLM representing the count result is obtained. The count output data DCLM is supplied to the read address signal forming unit 37, and the read address signal forming unit 37 represents a stereo left signal among a number of data segments constituting the audio data stored in the data memory unit 30. In response to the count output data DCLM, a read address control signal CRLM for sequentially reading in the order of addresses in the data memory unit 30 is formed and supplied to the data memory unit 30.
[0046]
In the clock count unit 36, only when the second frame pulse signal CFPR is supplied from the operation control unit 10, the clock signal CP is counted in synchronization with the second frame pulse signal CFPR. Count output data DCRM representing the count result is obtained. The count output data DCRM is supplied to the read address signal forming unit 38, and the read address signal forming unit 38 represents the stereo right signal among the many data segments constituting the audio data stored in the data memory unit 30. In accordance with the count output data DCRM, a read address control signal CRRM for sequentially reading in the order of addresses in the data memory unit 30 is formed and supplied to the data memory unit 30.
[0047]
As a result, a stereo left signal among a number of data segments constituting the audio data for each frame stored in sequence from the data memory unit 30 is set as a read address control signal CRLM. The data representing the stereo right signal among a number of data segments constituting the audio data for each frame that is sequentially read and stored in accordance with the setting of the read address. Are sequentially read in response to the read address control signal CRRM. The audio data representing the two-channel audio signal of the stereo left signal and the stereo right signal read out from the data memory unit 30 in units of frames is deinterleaved by the data segment constituting the audio data. Then, the processed audio data DQM in which one frame is successively connected is formed on the basis of the deinterleaved audio data having a normal arrangement order. The read address signal forming units 37 and 38 that supply the read address control signals CRLM and CRRM to the data memory unit 30 form a read control unit for the data memory unit 30.
[0048]
The audio data stored in the data memory unit 30 as described above is read in a state in which the deinterleave processing is performed on the plurality of data segments by the read address signal forming units 37 and 38 forming the read control unit. As a result, deinterleaving processing is performed on a plurality of interleaved data segments that constitute audio data representing 2-channel audio signals that are main information data in the audio information data DA. It will be.
[0049]
In this way, the processed audio data DQM, which is the deinterleaved audio data obtained from the data memory unit 30 in the main deinterleave processing unit 27, is a two-channel audio signal, that is, a stereo left signal and a stereo signal. The right signal is expressed as having an appropriate phase relationship. Then, the processed audio data DQM is supplied to the concealment processing unit 40. In the concealing processing unit 40, when the processed audio data DQM supplied includes a missing portion for the data segment constituting the processed audio data DQM, two pieces of data obtained immediately before and after the missing portion in the processed audio data DQM are obtained. An interpolated data segment representing an average value of the values represented by the data segments, that is, a binary interpolated data segment based on two data segments obtained before and after the missing part is formed, and the missing interpolated data segment is formed by the binary interpolated data segment. Is performed. Then, the concealment processing unit 40 sends out audio data DNM in which the missing portions of the data segments are filled.
[0050]
Note that when the processed audio data DQM supplied to the concealing processing unit 40 does not include a missing portion for the data segment constituting the processed audio data DQM, the processed audio data DQM is sent out as is from the concealing processing unit 40 as audio data DNM. The
[0051]
The audio data DNM obtained from the concealment processing unit 40 is supplied to the JOG data calculation unit 41. The JOG data calculation unit 41 forms a data interpolation processing unit, and the processed audio data DQM from the data memory unit 30 is obtained when a JOG playback mode state, for example, a 1 / 10-speed playback mode state is taken. For each set of two data segments adjacent to each other in the audio data DNM from the concealment processing unit 40, the contents of the JOG playback mode at that time are between the two data segments forming each set. Interpolated data segments formed by representing the interpolated values corresponding to the values corresponding to the values represented by the two data segments respectively, such as nine in the case of the corresponding number, for example, 1/10 times speed reproduction mode The calculation process that will be arranged is performed. Thereby, in the JOG data calculation unit 41, when the processed audio data DQM from the data memory unit 30 is obtained under the JOG playback mode state, it is compared with the audio data DNM from the concealment processing unit 40. Thus, audio data DJM having a higher sampling frequency is formed.
[0052]
If the processed audio data DQM from the data memory unit 30 is not obtained under the JOG playback mode state but is obtained under the normal playback mode state, JOG is used. The data calculation unit 41 does not affect the audio data DNM from the concealment processing unit 40, and the audio data DNM from the concealment processing unit 40 is directly used as the audio data DJM.
[0053]
The audio data DJM obtained from the JOG data calculation unit 41 in this way is supplied to the digital signal processor (DSP) 42 and subjected to preset digital processing. As a result, the DSP 42 obtains output audio data DAM based on which the two-channel audio signals of the stereo left signal and the stereo right signal are reproduced with an appropriate phase relationship. The output audio data DAM obtained from the DSP 42 is supplied to the selection contact 45A in the switch 45.
[0054]
Under such circumstances, the main deinterleaving processing unit 27, the concealing processing unit 40, the JOG data calculation unit 41, and the DSP 42 are connected to the audio information data DA obtained based on the digital composite data DT obtained from the reading rotary magnetic head unit 21. The audio data, which is the main information data in, is subjected to deinterleaving processing and predetermined digital processing for a plurality of data segments subjected to interleaving processing, so that two-channel audio signals of a stereo left signal and a stereo right signal are appropriate. A main data processing unit for obtaining output audio data DAM to be reproduced with a proper phase relationship is formed.
[0055]
On the other hand, in the sub-deinterleave processing unit 28, the audio information data DA obtained from the error correction / time axis correction unit 26 is supplied to a data memory unit 50 formed by, for example, a random access memory (RAM). At the same time, it is supplied to each of the byte count unit 51, the synchronization block number detection unit 52 and the track number detection unit 53.
[0056]
The data memory unit 50 is supplied with the write enable signal CEN from the operation control unit 10, and the data memory unit 50 can write data when the write enable signal CEN is at a low level, for example. When the write enable signal CEN is at a high level, data writing is disabled.
[0057]
The byte count unit 51, the synchronization block number detection unit 52, and the track number detection unit 53 correspond to the byte count unit 31, the synchronization block number detection unit 32, and the track number detection unit 33 in the main deinterleave processing unit 27, respectively. The byte count output signal SBC, the synchronization block number detection output signal SSD and the track number detection output signal SDT are transmitted in the same manner as the byte count unit 31, the synchronization block number detection unit 32 and the track number detection unit 33. Then, they are supplied to the write address signal forming unit 54.
[0058]
The write address signal forming unit 54 also corresponds to the write address signal forming unit 34 in the main deinterleave processing unit 27, operates in the same manner as the write address signal forming unit 34, and performs write address control. A signal CW is generated, and the write address control signal CW is supplied to the data memory unit 50.
[0059]
Thereby, in the data memory unit 50, the audio data in the audio information data DA supplied from the error correction / time axis correction unit 26 is configured while the write enable signal CEN is at a low level. A plurality of data segments that have been interleaved in units of frames are written by performing write address control according to the write address control signal CW. As a result, the audio data, which is the main information data in the audio information data DA, is in a state where the deinterleaving process has been performed on the plurality of data segments that have been subjected to the interleaving process, and is stored in the data memory unit 50. Will be stored.
[0060]
In the sub-deinterleave processing unit 28, the clock signal CP from the operation control unit 10 is supplied to each of the clock count unit 55 and the clock count unit 56. In each of the clock count unit 55 and the clock count unit 56, the clock signal CP is freely counted, and count output data DCLS representing the count result of the clock signal CP is obtained from the clock count unit 55, and Count output data DCRS representing the count result for the clock signal CP is obtained from the clock count unit 56.
[0061]
The count output data DCLS from the clock count unit 55 is supplied to the read address signal forming unit 57, and the read address signal forming unit 57 performs stereo among a number of data segments constituting the audio data stored in the data memory unit 50. A read address control signal CRLS for sequentially reading out the left signal in accordance with the count output data DCLS in the order of addresses in the data memory unit 50 is formed and supplied to the data memory unit 50.
[0062]
The count output data DCRS from the clock count unit 56 is supplied to the read address signal forming unit 58, and the read address signal forming unit 58 includes a number of data segments constituting audio data stored in the data memory unit 50. A read address control signal CRRS for sequentially reading out the stereo right signal is read out in the order of addresses in the data memory unit 50 in accordance with the count output data DCRS, and supplied to the data memory unit 50.
[0063]
As a result, the data left from the data memory unit 50 representing the stereo left signal among a number of data segments constituting the audio data for each frame sequentially stored therein is set to the read address control signal CRLS. The data representing the stereo right signal among a number of data segments constituting the audio data for each frame that is sequentially read and stored in accordance with the setting of the read address. Are sequentially read in response to the read address control signal CRRS. The audio data representing the two-channel audio signal of the stereo left signal and the stereo right signal read out from the data memory unit 50 in units of one frame is deinterleaved by the data segment constituting the audio data. As a result, the processed audio data DQS in which one frame is successively connected is formed based on the deinterleaved audio data having a normal arrangement order.
[0064]
The audio data stored in the data memory unit 50 as described above is read in a state in which the deinterleave processing for a plurality of data segments is performed by the read address signal forming units 57 and 58 forming the read control unit. As a result, deinterleaving processing is performed on a plurality of interleaved data segments that constitute audio data representing 2-channel audio signals that are main information data in the audio information data DA. It will be.
[0065]
In this way, the processed audio data DQS, which is the deinterleaved audio data obtained from the data memory unit 50 in the sub-deinterleave processing unit 28, is a two-channel audio signal, that is, a stereo left signal and a stereo signal. The right signal is represented, but the stereo left signal and the stereo right signal are not guaranteed to have an appropriate phase relationship. The processed audio data DQS is supplied to the concealment processing unit 60.
[0066]
In the concealment processing unit 60, when the supplied processed audio data DQS includes a missing part for the data segment constituting the processed audio data DQS, two pieces of data obtained immediately before and after the missing part in the processed audio data DQS are obtained. An interpolated data segment representing an average value of the values represented by the data segments, that is, a binary interpolated data segment based on two data segments obtained before and after the missing part is formed, and the missing interpolated data segment is formed by the binary interpolated data segment. Is performed. Then, the conceal processing unit 60 sends out the audio data DNS in which the missing portion of the data segment is filled.
[0067]
When the processed audio data DQS supplied to the concealment processing unit 60 does not include a missing portion for the data segment constituting the processed audio data DQS, the processed audio data DQS is sent from the concealment processing unit 60 as audio data DNS as it is. The
[0068]
The audio data DNS obtained from the conceal processing unit 60 is supplied to the JOG data calculation unit 61. The JOG data calculation unit 61 forms a data interpolation processing unit, and the processed audio data DQS from the data memory unit 50 is obtained when a JOG playback mode state, for example, a 1/10 speed playback mode state is taken. For each set of two data segments adjacent to each other in the audio data DNS from the concealment processing unit 60, the contents of the JOG playback mode at that time are set between the two data segments forming each set. An interpolated data segment formed by representing an interpolated value corresponding to a value corresponding to the value represented by each of the two data segments, for example, only nine in the case of the corresponding number, for example, in the case of the 1/10 speed reproduction operation mode, Arithmetic processing that will be arranged at intervals is performed. Thereby, in the JOG data calculation unit 61, when the processed audio data DQS from the data memory unit 50 is obtained under the JOG playback mode state, it is compared with the audio data DNS from the concealment processing unit 60. Thus, audio data DJS having a higher sampling frequency is formed.
[0069]
If the processed audio data DQS from the data memory unit 50 is not obtained under the JOG playback mode state but is obtained under the normal playback mode state, JOG is used. The data calculation unit 61 does not affect the audio data DNS from the conceal processing unit 60, and the audio data DNS from the conceal processing unit 60 is directly used as the audio data DJS.
[0070]
The audio data DJS obtained from the JOG data operation unit 61 in this way is supplied to the DSP 62 and subjected to preset digital processing. As a result, the DSP 62 obtains output audio data DAS from which two-channel audio signals of a stereo left signal and a stereo right signal are reproduced based on the DSP 62. The output audio data DAS obtained from the DSP 62 is supplied to the selection contact 45B in the switch 45.
[0071]
Under such circumstances, the sub-deinterleave processing unit 28, the concealment processing unit 60, the JOG data calculation unit 61, and the DSP 62 perform the audio information data DA obtained based on the digital composite data DT obtained from the reading rotary magnetic head unit 21. The sub data processing unit for obtaining the output audio data DAS is formed by performing deinterleaving processing and predetermined digital processing on the plurality of data segments subjected to the interleaving processing on the audio data which is the main information data.
[0072]
The switch 45 is supplied with a switch control signal CSW from the operation control unit 10. For example, when the switch control signal CSW takes a high level, the switch 45 has the movable contact 45C connected to the selection contact 45A, and when the switch control signal CSW takes a low level, the movable contact 45C turns to the selection contact 45B. The data selection unit is formed to selectively extract the output audio data DAM supplied to the selection contact 45A and the output audio data DAS supplied to the selection contact 45B through the movable contact 45C. .
[0073]
The switch control signal CSW sent from the operation control unit 10 indicates a stable state under each reproduction mode state that is supplied to the operation control unit 10 in the main part configured by the example shown in FIG. The level corresponding to the status signal CSL is expressed. When each playback mode state is set, the level is low until the stabilization is achieved, and the level of each playback mode state is stabilized. Take a level.
[0074]
Under such circumstances, in the example shown in FIG. 1 constituting the main part of the digital VTR, the digital composite data DT for the same one frame is repeatedly read from the magnetic tape TP, thereby reading from the magnetic tape TP. The read rotary magnetic head unit 21 reads the digital composite data DT from the magnetic tape TP under the still reproduction mode state in which a still image is reproduced based on the video information data DV. In some cases, the operation control unit 10 supplies the drive control signals DTP and DHD for the still reproduction mode to the magnetic tape driving unit 20 and the reading rotary magnetic head unit 21, respectively. In addition, the operation control unit 10 supplies a write enable signal CEN that takes a high level to the data memory unit 30 in the main deinterleave processing unit 27 and the data memory unit 50 in the sub deinterleave processing unit 28. Then, the data memory units 30 and 50 are brought into a state in which data writing is disabled.
[0075]
Thereby, when the reading rotary magnetic head unit 21 reads the digital composite data DT from the magnetic tape TP under the still reproduction mode state, the data memory unit 30 in the main deinterleave processing unit 27 The processed audio data DQM is not obtained, and the processed audio data DQS is not obtained from the data memory unit 50 in the sub-deinterleave processing unit 28. As a result, neither the output audio data DAM from the main data processing unit nor the output audio data DAS from the sub data processing unit is sent out. Therefore, at this time, the audio based on the audio information data read from the magnetic tape TP No playback is performed.
[0076]
With the example shown in FIG. 1 constituting the main part of the digital VTR being in the still reproduction mode state, the reading rotary magnetic head unit 21 starts operating from reading the digital composite data DT from the magnetic tape TP. The example shown in FIG. 1, which constitutes the main part of the digital VTR, is in a playback mode state different from the still playback mode state, for example, in the normal playback mode state, the reading rotary magnetic head unit 21 is a magnetic tape. Assuming that the digital composite data DT is read from the TP, the operation control unit 10 sends a drive control signal DTP for normal reproduction mode to the magnetic tape drive unit 20 and the read rotary magnetic head unit 21 at that time. And DHD, respectively. Thereby, the running speed of the magnetic tape TP driven by the magnetic tape drive unit 20 is made equal to the running speed during recording.
[0077]
In addition to this, the operation control unit 10 reads the rotating magnetic head unit for reading from the operating state in which the reading rotary magnetic head unit 21 reads the digital composite data DT from the magnetic tape TP under the still reproduction mode state. 21. When a transition is made to an operation state in which the digital composite data DT is read from the magnetic tape TP under a playback mode state different from the still playback mode state, for example, a normal playback mode state, The output audio data DAM is not obtained from the sub-data processor, the output audio data DAS is obtained from the sub-data processor, and the switch 45 operates so that the output audio data DAS from the sub-data processor is extracted. To do.
[0078]
Therefore, the operation control unit 10 supplies the write enable signal CEN that takes a low level to the data memory unit 30 in the main deinterleave processing unit 27 and the data memory unit 50 in the sub deinterleave processing unit 28, and the data memory unit 30 and 50 are in a state in which data can be written, and the clock signal CP is sent to the clock count units 35 and 36 in the main deinterleave processing unit 27 and the clock count units 55 and 56 in the sub deinterleave processing unit 28, respectively. Supply. However, under such circumstances, an appropriate phase between the two-channel audio signal represented by the audio data in the audio information data DA obtained from the error correction / time axis correction unit 26, that is, the stereo left signal and the stereo right signal is guaranteed. Since the state has not been reached, the operation control unit 10 guarantees an appropriate phase between the two-channel audio signal represented by the audio data in the audio information data DA, that is, the stereo left signal and the stereo right signal. The first frame pulse signal CFPL and the second frame pulse signal CFPR are not transmitted.
[0079]
Further, at this time, the status signal CSL supplied to the operation control unit 10 indicates that the playback mode state different from the post-transition still playback mode state, for example, the normal playback mode state has not been stabilized. Accordingly, the operation control unit 10 supplies the switch 45 with a switch control signal CSW that takes a low level.
[0080]
Under such circumstances, in the main deinterleave processing unit 27, the first and second frame pulse signals CFPL and CFPR are not supplied to the clock counting units 35 and 36, so that the clocks in the clock counting units 35 and 36 respectively. The count for the signal CP is not performed. Therefore, the read address control signals CRLM and CRRM cannot be obtained from the read address signal forming units 37 and 38. As a result, a number of data segments constituting the audio data from the data memory unit 30 are not read, and the processed audio data DQM is not formed. As a result, the DSP 42 in the main data processing unit is placed in a state where the output audio data DAM cannot be obtained.
[0081]
On the other hand, in the sub-deinterleave processing unit 28, each of the clock counting units 55 and 56 freely counts the clock signal CP supplied from the operation control unit 10, and accordingly, the reading is performed. Read address control signals CRLS and CRRS are obtained from the address signal forming portions 57 and 58. As a result, a number of data segments constituting audio data for each frame from the data memory unit 50 are sequentially read in accordance with the read address control signals CRLS and CRRS to form processed audio data DQS. As a result, the output audio data DAS is obtained from the DSP 62 in the sub data processing unit and supplied to the selection contact 45B of the switch 45.
[0082]
At this time, the switch 45 is supplied with a switch control signal CSW having a low level from the operation control unit 10, and the movable contact 45C is connected to the selection contact 45B. Thereby, the output audio data DAS obtained from the DSP 62 in the sub data processing unit is taken out through the selection contact 45B and the movable contact 45C of the switch 45. In this way, a reproduction audio signal based on the output audio data DAS extracted by the switch 45 is formed and used for sound reproduction.
[0083]
In such a case, the processed audio data DQS obtained from the data memory unit 50 in the sub-deinterleave processing unit 28 is a two-channel audio signal, that is, a stereo left signal and a stereo right signal are appropriately converted. Since the phase relationship is assumed not to be guaranteed, the output audio data DAS obtained from the DSP 62 in the sub data processing unit is based on the two channels of the stereo left signal and the stereo right signal. The audio signals are not reproduced with an appropriate phase relationship. Therefore, there is a possibility that the left and right sounds are not in an appropriate phase relationship in the sound that is reproduced by forming a two-channel reproduced audio signal based on the output audio data DAS extracted by the switch 45.
[0084]
Thereafter, the status signal CSL supplied to the operation control unit 10 indicates that a playback mode state different from the post-transition still playback mode state, for example, the normal playback mode state has been stabilized. When the two-phase audio signal represented by the audio data in the audio information data DA obtained from the error correction / time axis correction unit 26, that is, a state in which an appropriate phase between the stereo left signal and the stereo right signal can be guaranteed, the operation is performed. The control unit 10 obtains the output audio data DAS from the sub data processing unit and obtains the output audio data DAM from the main data processing unit, and outputs audio data from the main data processing unit by the switch 45. Operates to ensure that the DAM is removed.
[0085]
Therefore, the operation control unit 10 supplies the write enable signal CEN that takes a low level to the data memory unit 30 in the main deinterleave processing unit 27 and the data memory unit 50 in the sub deinterleave processing unit 28, and the data memory unit 30 and 50 are in a state in which data can be written, and the clock signal CP is sent to the clock count units 35 and 36 in the main deinterleave processing unit 27 and the clock count units 55 and 56 in the sub deinterleave processing unit 28, respectively. In addition, the first frame pulse signal CFPL and the second frame pulse signal CFPR are supplied to the clock count units 35 and 36 in the main deinterleave processing unit 27, respectively. Further, at this time, the operation control unit 10 supplies the switch 45 with a switch control signal CSW having a high level.
[0086]
Under such circumstances, in the main deinterleave processing section 27, the clock count section 35 counts the clock signal CP synchronized with the first frame pulse signal CFPL, and the clock count section 36 performs the second operation. The clock signal CP synchronized with the frame pulse signal CFPR is counted, and accordingly, the read address control signals CRLM and CRRM are obtained from the read address signal forming units 37 and 38, respectively. As a result, a number of data segments constituting audio data for one frame are sequentially read out from the data memory unit 30 in accordance with the read address control signals CRLM and CRRM, and two-channel audio signals, that is, stereo signals are read out. Processed audio data DQM is formed that represents the left signal and the stereo right signal as having an appropriate phase relationship. As a result, output audio data DAM is obtained from the DSP 42 in the main data processing unit, based on which the audio signals of the two channels of the stereo left signal and the stereo right signal are reproduced with an appropriate phase relationship. , And supplied to the selection contact 45A of the switch 45.
[0087]
In the sub-deinterleave processing unit 28, each of the clock counting units 55 and 56 continuously counts the clock signal CP supplied from the operation control unit 10, and accordingly, the read address Read address control signals CRLS and CRRS are obtained from the signal forming units 57 and 58. As a result, a number of data segments constituting audio data for each frame from the data memory unit 50 are sequentially read according to the read address control signals CRLS and CRRS to form processed audio data DQS. As a result, the output audio data DAS is obtained from the DSP 62 in the sub data processing section and supplied to the selection contact 45B of the switch 45.
[0088]
At this time, the switch 45 is supplied with a switch control signal CSW having a high level from the operation control unit 10, and the movable contact 45C is connected to the selection contact 45A. Thereby, the output audio data DAM obtained from the DSP 42 in the main data processing unit is taken out through the selection contact 45A and the movable contact 45C of the switch 45. In this way, a reproduction audio signal based on the output audio data DAM extracted by the switch 45 is formed and used for sound reproduction.
[0089]
In such a case, the processed audio data DQM obtained from the data memory unit 30 in the main deinterleave processing unit 27 has two phases of audio signals, that is, a stereo left signal and a stereo right signal in an appropriate phase. The output audio data DAM obtained from the DSP 42 in the main data processing unit is reproduced based on the two audio signals of the stereo left signal and the stereo right signal based on the phase relationship. It is supposed to be. Therefore, in the sound reproduced by forming a two-channel reproduction audio signal based on the output audio data DAM extracted by the switch 45, the left and right sounds have an appropriate phase relationship.
[0090]
As described above, according to the example shown in FIG. 1 constituting the main part of the digital VTR, the digital composite data DT from the magnetic tape TP by the read rotary magnetic head unit 21 under the still reproduction mode state. A playback mode state that is different from the still playback mode state from the state in which reading is performed and the main data processing unit including the main deinterleave processing unit 27 and the sub data processing unit including the sub deinterleave processing unit 28 are not operating normally. For example, the digital composite data DT is read from the magnetic tape TP by the reading rotary magnetic head unit 21 under the normal reproduction mode state, and the main data processing unit including the main deinterleave processing unit 27 and the sub data processing unit 27 are read. Even when the sub-data processing unit including the interleave processing unit 28 shifts to a state in which it normally operates, The sub data processing unit until output audio data DAM from which the two-channel audio signals of the stereo left signal and the stereo right signal are reproduced with an appropriate phase relationship from the main data processing unit is obtained. Therefore, the output audio data DAS is obtained, and therefore, the audio data subjected to the deinterleaving process is immediately applied without muting the output audio data or the reproduced audio signal of two channels based on the output audio data. The output audio data representing the two-channel audio signal of the stereo left signal and the stereo right signal is obtained.
[0091]
In the above-described example, the main data processing unit including the main deinterleaving processing unit 27, the sub data processing unit including the sub deinterleaving processing unit 28, and the digital data handled by the switch 45 are obtained in the digital VTR. The audio data included in the audio information data to be processed, the information processing apparatus according to the invention described in claim 1 or claim 2 in the claims of the present application, It is possible to handle various digital data other than audio data.
[0092]
【The invention's effect】
As is clear from the above description, according to the information processing apparatus according to the invention described in claim 1 or claim 2 in the scope of claims of the present application, for example, the first and second data processing units are properly The digital information data is read from the recording medium by the head unit under the specific reproduction mode state from the non-operating state, and the first and second data processing units shift to a normal operating state. In some cases, after the transition, the second output information data is obtained until the first output information data from which each of the information signals of the plurality of channels from the first data processing unit is reproduced with an appropriate phase relationship is obtained. The second output information data from the data processing unit is obtained, and therefore the muting state for the output information data or the reproduction information signal based thereon is not taken. Immediately, the output information data representing an information signal of a plurality of channels based on information deinterleaving processing has been performed the data is obtained.
[0093]
Further, according to the information processing apparatus according to the invention described in claim 3 or claim 4 in the claims of the present application, for example, video information data from the recording medium by the head unit in the still reproduction mode state And the audio information data are read out, and the first and second data processing units are not normally operated, so that the playback mode is different from the still playback mode, for example, the normal playback mode or the JOG playback mode. Even when the video information data and the audio information data are read from the recording medium by the head unit under the state and the first and second data processing units shift to a state in which they normally operate, Each of the audio signals of the plurality of channels from the first data processing unit is reproduced with an appropriate phase relationship. Until the first output audio data is obtained, the second output audio data from the second data processing unit is obtained. Therefore, the output audio data or the reproduced audio signal of a plurality of channels based on the output audio data is obtained. Immediately without being muted, output audio data representing a plurality of channels of audio signals based on the deinterleaved audio data is obtained.
[Brief description of the drawings]
FIG. 1 is a block connection diagram showing an example of an information processing apparatus according to any one of claims 1 to 4 in the claims of the present application, with a state constituting a main part of a digital VTR. is there.
2 is a conceptual diagram used for explaining scanning of an inclined recording track formed on a magnetic tape by a magnetic head provided in the example shown in FIG. 1;
FIG. 3 is a conceptual diagram showing an example of a recording format of a magnetic tape used with a digital VTR.
FIG. 4 is a conceptual diagram showing an example of a coding format of audio information data recorded on a magnetic tape by a digital VTR.
FIG. 5 is a conceptual diagram showing an example of a data format of audio data recorded on a magnetic tape by a digital VTR.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Operation control part, 20 ... Magnetic tape drive part, 21 ... Rotary magnetic head part for reading, 22 ... Reproduction amplifier part, 23 ... Equalizer part, 24 ... Data rearrangement , 25 ... Coding unit, 26 ... Error correction / time axis correction unit, 27 ... Main deinterleave processing unit, 28 ... Sub-deinterleave processing unit, 30, 50 ... Data memory unit , 31, 51... Byte count unit, 32, 52... Synchronous block number detection unit, 33, 53... Track number detection unit, 34, 54. , 55, 56... Clock count unit, 37, 38, 57, 58... Read address signal forming unit, 40, 60... Conceal processing unit, 41, 61. 62 ...・ DSP, 45 ... switch

Claims (4)

A recording medium on which digital information data is recorded, which is composed of a plurality of data segments subjected to interleave processing in units of predetermined data sections, and in which auxiliary information data is added to main information data representing information signals of a plurality of channels From the head portion that reads the digital information data under the selected playback mode state,
The main information data in the digital information data obtained from the head unit is subjected to deinterleaving processing and predetermined digital processing for the plurality of data segments subjected to the interleaving processing, so that each of the information signals of the plurality of channels is obtained. A first data processing unit for obtaining first output information data to be reproduced with an appropriate phase relationship;
The main information data in the digital information data obtained from the head unit is subjected to deinterleaving processing and predetermined digital processing for a plurality of data segments subjected to the interleaving processing, to obtain second output information data. Two data processing units;
A data selection section for selectively retrieving the first output information data and the second output information data;
When reading of the digital information data from the recording medium by the head unit is started under a specific reproduction mode state, first, the data selection unit is brought into a state of taking out the second output information data, Thereafter, when stabilization of the specific reproduction mode state is achieved, an operation control unit that shifts the data selection unit to a state of taking out the first output information data;
An information processing apparatus configured to include: The first data processing unit applies deinterleaving processing to a plurality of data segments subjected to interleaving processing to main information data in the digital information data obtained from the head unit, so that each of the information signals of the plurality of channels is appropriately processed. A first deinterleave processing unit that obtains first processed information data that will be represented with a correct phase relationship, and predetermined digital processing on the first processed information data obtained from the first deinterleave processing unit. And a first digital processing unit for obtaining first output information data. The second data processing unit performs interleaving processing on main information data in the digital information data obtained from the head unit. The second processed information data is deinterleaved with respect to the plurality of processed data segments. A second deinterleave processing unit for obtaining data, and a second digital for obtaining second output information data by subjecting the second processed information data obtained from the second deinterleave processing unit to predetermined digital processing The information processing apparatus according to claim 1, comprising a processing unit. Audio information data composed of video information data and a plurality of data segments that have been subjected to interleaving processing in units of predetermined data sections, and additional data added to audio data representing audio signals of a plurality of channels, A head unit for reading the video information data and the audio information data from a recorded recording medium under a selected reproduction mode state;
The audio data in the audio information data obtained from the head unit is subjected to deinterleaving processing and predetermined digital processing for the plurality of data segments subjected to the interleaving processing, so that each of the audio signals of the plurality of channels is appropriate. A first data processing unit for obtaining first output audio data to be reproduced with a correct phase relationship;
The audio data in the audio information data obtained from the head unit is subjected to deinterleaving processing and predetermined digital data processing for a plurality of data segments subjected to the interleaving processing, thereby obtaining second output audio data. Two data processing units;
A data selection section for selectively extracting the first output audio data and the second output audio data;
The reading of the video information data and the audio information data from the recording medium by the head unit shifts from a still reproduction mode state in which a still image is reproduced based on the video information data read from the recording medium. When starting under a playback mode state different from the still playback mode state, the data selection unit is first brought into a state of taking out the second output audio data, and then different from the still playback mode state. An operation control unit that shifts the data selection unit to a state of extracting the first output audio data when the reproduction mode state is stabilized;
An information processing apparatus configured to include: 4. The information processing apparatus according to claim 3, wherein the recording medium is a magnetic tape, and the head portion is a rotating magnetic head portion that reads video information data and audio information data from the magnetic tape.

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