JP4042610B2 - Data reproduction method and data reproduction apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a data reproduction method and a data reproduction apparatus suitable for application to, for example, a digital video tape recorder.
[0002]
Specifically, in the present invention, a reproducing head is N times (N is a predetermined number of times) on a tape on which a plurality of sync blocks corresponding to audio data for each predetermined time is recorded on one or a plurality of inclined tracks. (Integer greater than or equal to 2) to obtain audio data for a predetermined time based on the sync block reproduced at each predetermined time, and N times of scanning of the reproducing head for each predetermined time during variable speed reproduction For example, the sync block corresponding to the scan number corresponding to the largest number of sync blocks is used among the sync blocks reproduced in step 1, and the missing sample data is interpolated using at least the previous or subsequent valid sample data. By obtaining audio data for a predetermined time, sample data for different predetermined times are mixed That is intended according to the sound quality data reproducing method and data reproducing apparatus so as to suppress the deterioration of.
[0003]
[Prior art]
Conventionally, audio data composed of a plurality of sample data is divided for a predetermined time, for example, for one field or one frame, and a plurality of sync blocks are generated from the audio data for each predetermined time. A reproducing head scans N times (N is an integer of 2 or more) at a predetermined time on a tape on which a plurality of sync blocks corresponding to audio data are recorded on one or a plurality of inclined tracks, and is reproduced by the reproducing head. It is known that the sync block thus written is written in an address position corresponding to the sync block of the memory, and audio data for a predetermined time is obtained based on the sync block written in the memory at each predetermined time (for example, , See Patent Document 1).
[0004]
[Patent Document 1]
JP-A-11-196377
[0005]
[Problems to be solved by the invention]
In the case of obtaining audio data for a predetermined time using all the sync blocks written in the memory at a predetermined time as in Patent Document 1 described above, samples for a different predetermined time are included in the audio data for the predetermined time. Data is often mixed, resulting in noise and deterioration in sound quality.
[0006]
An object of the present invention is to suppress deterioration in sound quality due to mixing of predetermined time sample data with audio data for a predetermined time.
[0007]
[Means for Solving the Problems]
In the data reproduction method according to the present invention, audio data composed of a plurality of sample data is divided every predetermined time, a plurality of sync blocks are generated from the audio data for each predetermined time, and the audio data for each predetermined time is generated. The reproducing head scans N times (N is an integer of 2 or more) every predetermined time on a tape on which a plurality of sync blocks corresponding to the same are recorded on one or a plurality of inclined tracks, and the reproducing head at each predetermined time. In the data reproduction method for obtaining audio data for a predetermined time based on the sync block reproduced in step 1, at the time of variable speed reproduction, the first to first data reproduced by N scans of the reproduction head for each predetermined time, respectively. Among sync blocks corresponding to N scan numbers, the most sync blocks correspond to the corresponding scan number With using the sync blocks, the missing sample data interpolated with valid sample data before and after, and obtains audio data of the predetermined time.
[0008]
In the data reproduction device according to the present invention, audio data composed of a plurality of sample data is divided every predetermined time, and a plurality of sync blocks are generated from the audio data for each predetermined time. A reproducing head scans N times (N is an integer of 2 or more) at a predetermined time on a tape on which a plurality of sync blocks corresponding to audio data are recorded on one or a plurality of inclined tracks, and is reproduced by the reproducing head. A data reproduction apparatus for writing a sync block to an address position corresponding to the sync block of the memory and obtaining audio data for a predetermined time based on the sync block written to the memory at each predetermined time. At the time of playback, the number of scans within the specified time is counted on the sync block played by the playhead. A data writing means that adds a scan number indicating whether or not the data has been generated and writes the data to the memory, and at the time of variable speed reproduction, the audio data for a predetermined time is obtained based on the plurality of sync blocks written to the memory. Among the plurality of sync blocks, a sync block corresponding to the scan number corresponding to the most sync blocks is used, and data processing means for interpolating the missing sample data using the preceding and succeeding valid sample data is provided. Is.
[0009]
In the present invention, audio data composed of a plurality of sample data is divided every predetermined time, for example, every field, and a plurality of sync blocks are generated from the audio data for each predetermined time, and each predetermined time is obtained. A plurality of sync blocks corresponding to the audio data are recorded on one or a plurality of inclined tracks on the tape.
[0010]
For example, audio data for a predetermined time is divided into one or a plurality of coding units, and error correction coding using a product code is performed for each of the divided coding units. The sync block described above is formed by adding the inner code parity to the audio data or the outer code parity data string constituting the inner code calculation data sequence.
[0011]
At the time of reproduction, the above-mentioned tape is scanned N times (N is an integer of 2 or more) every predetermined time by the reproducing head. Then, audio data for a predetermined time is obtained based on the sync block reproduced by the reproducing head at each predetermined time. For example, a sync block reproduced by the playback head is written at an address position corresponding to the sync block in the memory, and audio data for a predetermined time is obtained at each predetermined time based on the sync block written in the memory. It is done.
[0012]
For example, each reproduced sync block has a track ID for identifying which sync block is recorded in one or a plurality of inclined tracks in which the sync block for a predetermined time is recorded, and A sync block ID for identifying which sync block is a sync block among a plurality of sync blocks recorded on the inclined track is recorded. In this case, the address position of the memory described above is determined based on these track ID and sync block ID.
[0013]
At the time of variable speed reproduction, among the sync blocks corresponding to the first to Nth scan numbers respectively reproduced by N scans of the reproduction head for each predetermined time, the most sync blocks correspond to the corresponding scan numbers. The sync block is used to obtain audio data for a predetermined time. For example, at the time of variable speed reproduction, the sync block reproduced by the reproducing head is added with a scan number indicating the number of scans reproduced within a predetermined time and written to the memory. When obtaining audio data for a predetermined time, a sync block corresponding to the scan number corresponding to the most sync blocks among a plurality of sync blocks written in the memory is used.
[0014]
In this case, the missing sample data is interpolated using at least valid sample data before or after. For example, the effective sample data immediately before is used as interpolation data as it is. Further, for example, the effective sample data before and after is averaged to obtain interpolation data.
[0015]
When all of the sync blocks reproduced by N scans are used, there is a high possibility that audio data for a predetermined time is mixed with sample data for a different predetermined time. As described above, at the time of variable speed reproduction, the sync block corresponding to the scan number corresponding to the most sync block among the sync blocks reproduced by N scans of the reproducing head for each predetermined time is used. The possibility that sample data for a predetermined time period is mixed with audio data for a predetermined time period can be reduced. Thereby, deterioration of sound quality due to mixing of sample data for different predetermined times during variable speed reproduction can be suppressed.
[0016]
If the sync block is added with a segment number that identifies each predetermined time period with a plurality of predetermined time periods, the sync block corresponding to the scan number corresponding to the most sync block is used. Instead, sync blocks corresponding to combinations of scan numbers and segment numbers corresponding to the most sync blocks may be used. Also in this case, it is possible to reduce the possibility that sample data for a predetermined time is mixed with audio data for a predetermined time, and it is possible to suppress deterioration in sound quality.
[0017]
In this case, the sync block corresponding to the segment number corresponding to the most sync blocks may be used. In that case, the longitudinal interval Da of the scan position on the tape in the first and last scans of N scans within a predetermined time is a plurality of inclined tracks in which a plurality of sync blocks for a predetermined time are recorded. When the distance Db in the longitudinal direction on the tape occupies is exceeded, there is a possibility that sync blocks corresponding to the same segment number exist in sync blocks corresponding to the same segment number. As described above, the determination based on the combination of the segment number and the scan number can reduce the possibility that sync blocks for different predetermined times exist in the used sync blocks.
[0018]
In addition, if a sync block is added with a segment number that identifies each predetermined time with a period of a plurality of predetermined times, the sync block corresponding to the scan number corresponding to the most sync block is used. Instead, if Da> Db, the most sync blocks use the sync block corresponding to the combination of the corresponding scan number and segment number, and if Da ≦ Db, the most sync A sync block corresponding to a segment number corresponding to the block may be used.
[0019]
When Da ≦ Db, there is no possibility that sync blocks corresponding to the same segment number exist in sync blocks reproduced at each predetermined time, and there is no possibility that sync blocks for different predetermined times exist, and only the segment number is used for determination. There is no problem. In this case, the number of usable sync blocks can be increased, the number of sample data to be interpolated can be decreased, and the sound quality can be improved.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a basic configuration of a recording / reproducing apparatus 100 as an embodiment.
[0021]
First, the recording system will be described. Digital video data Vin input to the input terminal 11 11 V is supplied to the video compression circuit 112. In the video compression circuit 112, the video data Vin is divided into two-dimensional blocks of 8 × 8 pixels, for example, and data compression processing using block coding such as DCT is performed.
[0022]
Video data (compression encoded data) VDa output from the video compression circuit 112 is supplied to the ECC encoder 113. The ECC encoder 113 is supplied with digital audio data Ain input to the input terminal 111A. As for the audio data Ain, audio data for 12 channels can be input in parallel.
[0023]
The ECC encoder 113 performs error correction encoding using a product code for each encoding unit on the video data VDa, and error correction encoding using a product code for each encoding unit on the audio data Ain. Is done. The recording data (error correction encoded data) DDb output from the ECC encoder 113 is supplied to the recording head Hr via the recording amplifier 114 and is sequentially recorded on the inclined track of the magnetic tape 120.
[0024]
In this case, the recording data DDb is recorded in the form of NRZ (Non-Return-to-Zero) without going through digital modulation processing. However, the recording data DDb may be recorded after being subjected to digital modulation processing.
[0025]
Next, the reproduction system will be described. A reproduction signal reproduced by the reproduction head Hp from the inclined track of the magnetic tape 120 is amplified by the reproduction amplifier 131, further subjected to waveform equalization by the equalization circuit 132, and then supplied to the decoding circuit 133. The decoding circuit 133 performs decoding processing using, for example, a Viterbi algorithm on the reproduction signal after waveform equalization, and reproduction data corresponding to the recording data DDb output from the recording system ECC encoder 113 described above. DDc is obtained.
[0026]
The reproduction data DDc output from the decoding circuit 133 is supplied to the ECC decoder 134. In the ECC decoder 134, error correction is performed on each of the video data and the audio data using the parity (C1 parity, C2 parity) added to the reproduction data DDc.
[0027]
The error-corrected video data (compression encoded data) VDd output from the ECC decoder 134 is supplied to the video decompression circuit 135. In this video decompression circuit 135, data decompression is performed by a process reverse to that of the video compression circuit 112 of the recording system. The video data Vout output from the video decompression circuit 135 is output to the output terminal 136V. Also, the error-corrected audio data Aout output from the ECC decoder 134 is output to the output terminal 136A.
[0028]
FIG. 2 shows a recording format of the magnetic tape 120. On the magnetic tape 120, tracks T that are inclined with respect to the longitudinal direction are sequentially formed. In this case, the recording azimuths of two tracks T adjacent to each other are made different.
[0029]
The areas on the scanning start end side and the scanning end end side of the track T are the video data area ARV, respectively. _L , ARV _U Assigned to. This video data area ARV _L , ARV _U Is recorded with a sync block relating to video data, which constitutes the recording data DDb, output from the ECC encoder 113 described above.
[0030]
Also, the video area ARV of track T _L , ARV _U The area sandwiched between is assigned to the audio data area ARA. In the audio data area ARA, sync blocks related to the audio data constituting the recording data DDb output from the ECC encoder 113 are recorded.
[0031]
FIG. 3 is a schematic diagram showing the configuration of the rotating drum of the recording / reproducing apparatus 100 shown in FIG. The magnetic tape 120 is wound around the rotating drum 140 at an angle of 180 degrees. The magnetic tape 120 travels at a predetermined speed while being wound around the rotary drum 140 in this manner.
[0032]
In addition, four recording heads RECA to RECD are arranged on the rotary drum 140, and four recording heads RECE to RECH are arranged at an angular interval of 180 degrees with respect to these four recording heads RECA to RECD. Has been placed. Further, on the rotating drum 140, eight reproducing heads PBA to PBH corresponding to the recording heads RECA to RECH are arranged at an angular interval of 90 degrees with respect to the recording heads RECA to RECH, respectively.
[0033]
The recording head Hr of the recording / reproducing apparatus 100 shown in FIG. 1 is actually composed of eight recording heads RECA to RECH as described above. Further, the reproducing head Hp of the recording / reproducing apparatus 100 shown in FIG. 1 is actually composed of eight reproducing heads PBA to PBH as described above. Video data and audio data for one field are recorded on 12 tracks. At the time of recording and reproduction, four tracks are simultaneously scanned by four heads in one scan (scan), and therefore, 12 tracks are scanned by three scans.
[0034]
Video data area ARV of 12 tracks _L , ARV _U As shown in FIG. 4, 36 ECC blocks (coding unit data) from block 0 to block 35 are recorded. One ECC block is configured as follows. That is, for video data having a data array of 226 bytes × 114 bytes, for each outer code calculation data sequence indicated by arrow b, each column of data (data sequence) is encoded by, for example, (126, 114) Reed-Solomon code. Thus, 12-byte C2 parity (outer code parity) is generated. Further, for these video data and C2 parity, for each inner code calculation data sequence indicated by arrow a, the data (data string) in each row is encoded by, for example, (242, 226) Reed-Solomon code, and 16 bytes of C1 parity. Is generated. In addition, sync data and ID each having a size of 2 bytes are arranged at the head of each data row.
[0035]
FIG. 5 shows the configuration of one sync block in the ECC block (video data). The first two bytes are sync data. The following 2 bytes are ID. This ID includes a track ID for identifying which of the 12 tracks the one sync block is recorded on, and which of the plurality of sync blocks is recorded on one inclined track. A sync block ID to be identified is included.
[0036]
For example, the sync block ID is configured as 9-bit data. In this case, 1-bit video data area ARV on the scanning start end side _L Or the video data area ARV on the scanning end side _U It is assumed that it is recorded in In the remaining 8 bits, the area ARV _L , ARV _U A numerical value of 0 to 188 is given corresponding to each of the 189 sync blocks recorded in each of.
[0037]
In addition, one segment is formed for every 12 tracks, and segment numbers of 0 to 3 are repeatedly given. The above-mentioned 2-byte ID is a segment indicating the segment number of the segment in which the one sync block is recorded. An ID is also included.
[0038]
This ID is followed by 226 bytes of video data (or C2 parity) and 16 bytes of C1 parity.
[0039]
As described above, 36 ECC blocks (see FIG. 4) are recorded on 12 tracks of the magnetic tape 120. FIG. 6 shows a video data area ARV of 12 tracks constituting one segment. _L , ARV _U The arrangement of the sync block of each ECC block in FIG.
[0040]
As shown in FIG. 6A, for the four tracks 0 to 3 scanned for the first time, the video data area ARV _L In the ECC block of 0 to 35, 21Row sync blocks from 0Row to 20Row are recorded, and the video data area ARV is recorded. _U Is recorded with 21Row sync blocks from 21Row to 41Row in 0 to 35 ECC blocks.
[0041]
In addition, with respect to 4 to 4 tracks scanned for the second time, the video data area ARV _L 21 to 21 Row sync blocks from 42 Row to 62 Row in 0 to 35 ECC blocks are recorded in the video data area ARV. _U 21 row sync blocks from 63 Row to 83 Row in 0 to 35 ECC blocks are recorded.
[0042]
Further, regarding the 4 tracks 8 to 11 scanned for the third time, the video data area ARV _L In the ECC block of 0 to 35, 21Row sync blocks from 84Row to 104Row are recorded, and the video data area ARV is recorded. _U In 21 ECC blocks of 0 to 35, 21 Row sync blocks from 105 Row to 125 Row are recorded.
[0043]
Here, the 0Row sync block is composed of the 0th sync block in each of the 0 to 35 ECC blocks, and these 36 sync blocks are arranged on tracks 0 to 4 as shown in FIG. 6B. Nine sync blocks are sorted and recorded. That is, the 0th sync block in the 0, 18, 1, 19, 2, 20, 3, 21, 4 ECC block is recorded in the 0 track, and the 22, 5, 23, 6, and 6 are recorded in the 1 track. The 0th sync block in the 24, 7, 25, 8, 26 ECC blocks is recorded, and the 0th in the 9, 27, 10, 28, 11, 29, 12, 30, 13 ECC blocks are recorded in the second track. Sync blocks are recorded, and the third sync block is recorded on the third track in the ECC blocks 31, 14, 32, 15, 33, 16, 34, 17, and 35.
[0044]
Similarly, the 1 to 125 Row sync blocks are the 1st to 125th sync blocks in the 0 to 35 ECC blocks, and each of the 36 sync blocks is divided into 9 sync blocks for the corresponding 4 tracks. And recorded. In this case, for each row, the ECC block from which nine sync blocks recorded on each of the four tracks are extracted is rotated. As shown in FIG. 6C, one sync block includes 2-byte sync data, 2-byte ID, 226-byte video data (or C2 parity), and 16-byte C1 parity.
[0045]
Here, sync blocks of 0 Row to 125 Row are sequentially recorded on 12 tracks of 0 to 11. In this case, the sync blocks of 0 Row to 113 Row are obtained by adding C1 parity to the data sequence of the video data constituting the inner code calculation data sequence, while the sync blocks of 114 Row to 125 Row are the inner code calculation data sequence. C1 parity is added to the data string of C2 parity that constitutes.
[0046]
That is, in the present embodiment, when 36 ECC blocks of 0 to 35 are recorded on 12 tracks, as shown in FIG. 7, the data sequence of the video data constituting the inner code calculation data sequence is initially set. The first sync block to which the C1 parity is added is sequentially recorded, and after the recording of the first sync block is completed, the C1 parity is added to the C2 parity data string constituting the inner code calculation data sequence. The second sync block is sequentially recorded.
[0047]
In the 12-track audio data area ARA, 24 ECC blocks (coding unit data) from block 0 to block 23 are recorded as shown in FIG. One ECC block is configured as follows. That is, for audio data having a data arrangement of 189 bytes × 8 bytes, for each outer code calculation data sequence indicated by the arrow b, each column of data (data sequence) is encoded by (16, 8) Reed-Solomon code, for example. 8 bytes of C2 parity (outer code parity) is generated. Furthermore, for these audio data and C2 parity, for each inner code calculation data sequence indicated by arrow a, each row of data (data string) is encoded by, for example, (205, 189) Reed-Solomon code, and 16 bytes of C1 parity. Is generated. In addition, sync data and ID each having a size of 2 bytes are arranged at the head of each data row.
[0048]
FIG. 9 shows the configuration of one sync block in the ECC block (audio data). The first two bytes are sync data. The following 2 bytes are ID. This ID includes a track ID for identifying which of the 12 tracks the one sync block is recorded on, and which of the plurality of sync blocks is recorded on one inclined track. A sync block ID to be identified is included.
[0049]
For example, the sync block ID is configured as 9-bit data. In this case, one bit represents whether the audio data area ARA is recorded in the first half portion on the scanning start end side or the second half portion on the scanning end end side. In the remaining 8 bits, numerical values of 224 to 227, 232 to 235, 240 to 243, and 248 to 251 are given corresponding to the 16 sync blocks recorded in the first half and the second half, respectively.
[0050]
In addition, one segment is formed for every 12 tracks, and segment numbers of 0 to 3 are repeatedly given. The above-mentioned 2-byte ID is a segment indicating the segment number of the segment in which the one sync block is recorded. An ID is also included. That is, a segment number for identifying each field is added to the sync block with a period of four fields.
This ID is followed by 189 bytes of video data (or C2 parity) and 16 bytes of C1 parity.
[0051]
Here, two ECC blocks include one field of audio data for one channel, and thus twelve ECC blocks include one field of audio data for 12 channels. In this case, audio data of N channels (N = 0 to 11) is included in ECC blocks of block N and block N + 12.
[0052]
FIG. 10 shows sample data of audio data for one field arranged in the ECC blocks of block N and block N + 12. In this embodiment, it is assumed that the frame frequency is 23.97 Hz and the sampling frequency of audio data is 48 kHz, and the number of sample data per field is 1001 from S0 to S1000. One sample of data consists of 24 bits.
[0053]
In the ECC block of block N, even-numbered sample data of S0, S2, S4,..., S1000 are arranged so as to be continuous along the outer code calculation data sequence indicated by the arrow b. On the other hand, in the ECC block of block N + 12, odd-numbered sample data of S1, S3, S5,..., S999 are arranged so as to be continuous along the outer code calculation data sequence indicated by the arrow b. Data 0-0 to data 5-2 indicate auxiliary data such as format and time code.
[0054]
As described above, 24 ECC blocks (see FIG. 8) are recorded on 12 tracks of the magnetic tape 120. FIG. 11 shows the arrangement of the sync block of each ECC block in the audio data area ARA of 12 tracks constituting one segment.
[0055]
As shown in FIG. 11A, there are eight recording portions A1 to A8 in the audio data area ARA in four tracks 0 to 3 scanned for the first time, and 4 to 7 scanned for the second time. In the audio data area ARA in four tracks, there are eight recording sections A9 to A12 and A1 to A4, and further in the audio data area ARA in four tracks 8 to 11 scanned for the third time, A5 to A12. There are eight recording sections.
[0056]
As shown in FIG. 11B, sync blocks of ECC blocks each including audio data of 0 to 11 channels are recorded in the recording units A1 to A12. That is, the sync blocks of N and N + 12 ECC blocks including N channel (N = 0 to 11) audio data are allocated and recorded in two recording sections A (N + 1), respectively.
[0057]
In FIG. 11B, xyF indicates that the first half sync block in the x and y ECC blocks is recorded, and xyB indicates that the second half sync block in the x and y ECC blocks is recorded. Show. In this case, the first half sync block includes the 0th to 7th sync blocks of the x ECC block and the 8th to 15th sync block of the y ECC block, and the latter sync block includes the x ECC block. 8th to 15th sync blocks and 0th to 7th sync blocks of the ECC block of y are included.
[0058]
For example, the first 16 sync blocks in 0 and 12 ECC blocks including 0-channel audio data are recorded in the recording unit A1 in 4 tracks 0 to 3, and the recording unit in 4 tracks 4 to 7 is recorded. In A1, 16 sync blocks in the latter half of 0 and 12 ECC blocks including audio data of 0 channel are recorded.
[0059]
As shown in FIG. 11C, one sync block includes 2-byte sync data, 2-byte ID, 189-byte audio data (or C2 parity), and 16-byte C1 parity.
[0060]
Next, details of the ECC encoder 113 in the recording / reproducing apparatus 100 shown in FIG. 1 will be described. FIG. 12 shows the configuration of the ECC encoder 113.
[0061]
The ECC encoder 113 includes an SDRAM (Synchronous Dynamic RAM) 151 and an SDRAM interface 152 that is an interface for performing writing and reading with respect to the SDRAM 151. The SDRAM 151 has a capacity capable of storing video data and audio data of a plurality of fields, for example, 6 fields.
[0062]
In this case, in the SDRAM 151, for video data, a memory space corresponding to 36 ECC blocks (see FIG. 4) is prepared for each field. Further, in the SDRAM 151, for audio data, a memory space corresponding to 24 ECC blocks (see FIG. 8) is prepared for each field.
[0063]
The ECC encoder 113 has a video input write buffer 153V serving as a buffer for writing the video data (compression encoded data) VDa supplied from the video compression circuit 112 (see FIG. 1) to the SDRAM 151. Here, the buffer 153V also constitutes packing means, and packs the video data (compression encoded data) VDa supplied from the video compression circuit 112 into a sync block.
[0064]
As described above, in the video compression circuit 112, the video data Vin is divided into two-dimensional blocks of 8 × 8 pixels, for example, and data compression processing using block coding such as DCT is performed. Although not described above, the effective screen is composed of 1920 pixels × 1088 lines. In the input write buffer 153V, as shown in FIG. 13, two sync blocks Sd are provided for each compression encoded data of a macro block of 16 × 16 pixels (four DCT blocks of 8 × 8 pixels). , Sh.
[0065]
Here, the sync block Sd constitutes a first sync block, and is a sync block that can be used when reproduced alone during variable speed reproduction. The sync block Sd is packed with coefficients in a low frequency region including DC coefficients. The sync block Sh constitutes a second sync block, and is a sync block that cannot be used when reproduced alone during variable speed reproduction. The sync block Sh is packed with high frequency domain coefficients excluding the coefficients packed into the sync block Sd.
[0066]
In the SDRAM 151, sync blocks Sd and Sh packed with compression encoded data of each macroblock are sequentially written in a memory space corresponding to 36 ECC blocks for each field. As shown in FIG. 6, each of the 36 ECC blocks is shuffled and recorded on the inclined track. When the sync blocks Sd and Sh packed with the compression encoded data of each macro block are written in the memory space corresponding to the 36 ECC blocks of the SDRAM 151, as shown in FIG. The write address in the SDRAM 151 is controlled so that Sd and Sh are continuously recorded. In FIG. 14, an arrow SCN indicates an example of the scanning trajectory of the reproducing head during variable speed reproduction.
[0067]
That is, when each sync block of 36 ECC blocks is recorded as shown in FIG. 6B, 0th sync block of 0,18 ECC block, 0th sync block of 1,19 ECC block, 2 , 20, the sync blocks Sd and Sh related to the same macro block are written in the memory space corresponding to the 0th sync block of the ECC block.
[0068]
Returning to FIG. 12, the ECC encoder 113 also reads out, for each field, a buffer for supplying video data corresponding to 36 ECC blocks related to video data read from the SDRAM 151 to a video C2 encoder 155V described later. And a video C2 encoder 155V for calculating C2 parity (outer code parity) in 36 ECC blocks related to the video data for each field.
[0069]
In this case, the C2 encoder 155V has, for example, 36 computing units that compute C2 parity, and can compute C2 parity in the 36 ECC blocks described above in parallel. Therefore, video data corresponding to 36 ECC blocks is supplied from the buffer 154V to the C2 encoder 155V in parallel.
[0070]
Further, the ECC encoder 113 has a video C2 write buffer 156V serving as a buffer for writing the C2 parity in the 36 ECC blocks calculated by the C2 encoder 155V into the SDRAM 151 for each field.
[0071]
Further, the ECC encoder 113 includes an audio input buffer 153A for supplying audio data Ain inputted to the input terminal 111A (see FIG. 1) to an audio C2 encoder 155A described later, and 24 pieces of audio data for each field. And an audio C2 encoder 155A for calculating C2 parity (outer code parity) in the ECC block.
[0072]
Further, the ECC encoder 113 has an audio C2 write buffer 156A serving as a buffer for writing the audio data Ain and the C2 parity calculated by the C2 encoder 155A into the SDRAM 151 for each field. In the SDRAM 151, audio data Ain and C2 parity of each channel are sequentially written in a memory space corresponding to two ECC blocks for each field.
[0073]
Further, the ECC encoder 113 reads out, from each SDRAM 151, video data and C2 parity corresponding to 36 ECC blocks related to video data, audio data corresponding to 24 ECC blocks related to audio data, and An output buffer 157 serving as a buffer for outputting C2 parity is provided.
[0074]
Further, the ECC encoder 113 includes a SYNC / ID adding circuit 158 for adding sync data and ID to the data sequence of each sync block related to video data or audio data output from the output buffer 157 in the recording order, and this SYNC / ID. The additional circuit 158 has a C1 encoder 159 that calculates and adds C1 parity to the video data of each sync block to which sync data and ID are added, and outputs the result as recording data DDb. In this case, the C1 encoder 159 is used for both video and audio, and is used with parameters such as code length set at the beginning of the sync block.
[0075]
The operation of the ECC encoder 113 shown in FIG. 12 will be described.
Video data (compression encoded data) VDa supplied from the video compression circuit 112 (see FIG. 1) is written to the SDRAM 151 via the video input write buffer 153V and the SDRAM interface 152. In this case, each 16 × 16 pixel macroblock compression-coded data is packed into two sync blocks Sd and Sh, and these sync blocks Sd and Sh correspond to 36 ECC blocks for each field. Sequentially written to memory space.
[0076]
In this case, the write address in the SDRAM 151 is controlled so that the sync blocks Sd and Sh related to the same macroblock are continuously recorded on the inclined track (see FIG. 14). Here, the sync block Sd constitutes a first sync block that can be used when reproduced independently during variable speed reproduction. The sync block Sd is packed with coefficients in a low frequency region including DC coefficients. The sync block Sh constitutes a second sync block that cannot be used when reproduced independently during variable speed reproduction. The sync block Sh is packed with high frequency domain coefficients excluding the coefficients packed into the sync block Sd.
[0077]
For each field, the video data corresponding to the 36 ECC blocks related to the video data read from the SDRAM 151 is supplied to the video C2 encoder 155V via the SDRAM interface 152 and the video C2 read buffer 154V. In this case, video data corresponding to 36 ECC blocks is supplied from the buffer 154V to the C2 encoder 155V in parallel.
[0078]
In the C2 encoder 155V, C2 parities in 36 ECC blocks are calculated in parallel by 36 calculators for each field. Thus, for each field, the C2 parity in the 36 ECC blocks calculated by the C2 encoder 155V is stored in the memory of the corresponding 36 ECC blocks in the SDRAM 151 via the video C2 write buffer 156V and the SDRAM interface 152. It is written in the C2 parity area in space.
[0079]
The audio data Ain supplied from the input terminal 111A (see FIG. 1) is supplied to the audio C2 encoder 155A via the audio input buffer 153A. In the C2 encoder 155A, C2 parity in 24 ECC blocks is calculated for each field.
[0080]
For each field, the C2 parity and audio data Ain in the 24 ECC blocks calculated by the C2 encoder 155A are stored in the memory of the corresponding 24 ECC blocks in the SDRAM 151 via the audio C2 write buffer 156A and the SDRAM interface 152. Written in space.
[0081]
For each field, video data and C2 parity corresponding to 36 ECC blocks related to video data and audio data and C2 parity corresponding to 24 ECC blocks related to audio data read from SDRAM 151 are SDRAM. This is supplied to the output buffer 157 via the interface 152. Each sync block relating to video data or audio data output from the output buffer 157 in the recording order is supplied to the C1 encoder 159 after the sync data and ID are added by the SYNC / ID adding circuit 158.
[0082]
In the C1 encoder 159, C1 parity is calculated and added to the video data of each sync block to which sync data and ID are added, and each sync block is generated as recording data DDb. The recording data Db is supplied to the recording amplifier 114 (see FIG. 1) as described above.
[0083]
Next, details of the ECC decoder 134 in the recording / reproducing apparatus 100 shown in FIG. 1 will be described. FIG. 15 shows the configuration of the ECC decoder 134.
[0084]
The ECC decoder 134 includes a SYNC detection circuit 161 for detecting sync data of each sync block constituting the reproduction data DDc supplied from the decoding circuit 133 (see FIG. 1), and each sync supplied through the SYNC detection circuit 161. Each block includes a C1 decoder 162 that performs error correction processing using C1 parity. In this case, the C1 decoder 162 is used for both video and audio, and a parameter such as a code length is set and used at the beginning of the sync block.
[0085]
Each sync block is output from the C1 decoder 162 with an error correction flag and ID indicating whether or not error correction has been performed added to the video data sequence or audio data sequence after the error correction processing. The error correction flag is inserted into the sync data portion. In this case, if the error correction flag is in a state indicating that the error correction has been completed, the data string to which the error correction flag is added does not include an error, while the error correction flag is error correction. Is in a state indicating that the error cannot be performed, the data string to which the error correction flag is added includes an error.
[0086]
The ECC decoder 134 includes an SDRAM 163 and an SDRAM interface 164 that is an interface for performing writing and reading with respect to the SDRAM 163. The SDRAM 163 has a capacity capable of storing a plurality of fields, for example, six fields of video data and audio data.
[0087]
In this case, the SDRAM 163 has a memory space corresponding to 36 ECC blocks (see FIG. 4) for each field for video data. In addition, in the SDRAM 163, for audio data, a memory space corresponding to 24 ECC blocks (see FIG. 8) is prepared for each field.
[0088]
The ECC decoder 134 has an input write buffer 165 serving as a buffer for writing each sync block supplied from the C1 decoder 162 to the SDRAM 163.
[0089]
Here, during normal reproduction, the input write buffer 165 performs error correction processing using C2 parity by the C2 decoder, as will be described later, so that all of the input write buffer 165 does not depend on the state of the added error correction flag. Write the sync block to the SDRAM 163.
[0090]
In this case, each sync block related to the video data is written at a predetermined address position in the memory space corresponding to 36 ECC blocks for each field based on the track ID and sync block ID added thereto. As a result, 36 ECC blocks, each consisting of 126 sync blocks similar to those at the time of recording, are generated in the SDRAM 163.
[0091]
In this case, each sync block related to the audio data is written at a predetermined address position in the memory space corresponding to 24 ECC blocks for each field based on the track ID and sync block ID added thereto. As a result, 24 ECC blocks are generated in the SDRAM 163 for each field, each consisting of 16 sync blocks similar to those at the time of recording.
[0092]
In addition, the input write buffer 165 is the following among the sync blocks supplied from the C1 decoder 162 for video data during variable speed playback in which playback is performed with the running speed of the magnetic tape 120 being faster or slower than during normal playback. Only the sync block selected in the selection process is written into the SDRAM 163. Also in this case, each sync block is written at a predetermined address position in the memory space corresponding to 36 ECC blocks based on the track ID and sync block ID added thereto. In this case, writing is performed in the same memory space in each field, and the stored data is sequentially updated.
[0093]
The flowchart of FIG. 16 shows the procedure of the selection process.
Processing is started in step ST1, and in step ST2, it is determined whether the reproduced sync block is one of the sync blocks Sd and Sh. This determination is made based on the sync block ID. When it is determined that the block is the sync block Sd, it is determined in step ST3 whether or not the sync block has been error-corrected by the C1 parity. This determination is made based on the error correction flag.
[0094]
If the error has been corrected, the sync block is selected as a write sync block in step ST4, and the process ends in step ST5. On the other hand, if the error cannot be corrected, in step ST6, the sync block is not selected as a write sync block, and the process ends in step ST5.
[0095]
When it is determined in step ST2 that it is a sync block Sh, it is determined in step ST7 whether or not the sync block Sd reproduced immediately before has been error-corrected and selected as a write sync block. If it is selected as a write sync block, it is determined in step ST8 whether or not the sync block is related to the same macro block as the sync block Sd reproduced immediately before. This determination is made based on the track ID and sync block ID.
[0096]
That is, the track ID in the sync block is the same as the track ID in the sync block Sd reproduced immediately before, and the sync block ID in the sync block is continuous with the sync block ID in the sync block Sd reproduced immediately before In this case, the sync block is determined to be related to the same macro block as the sync block Sd reproduced immediately before.
[0097]
When it is determined in step ST8 that the blocks are related to the same macroblock, it is determined in step ST9 whether or not the sync block has been error-corrected by C1 parity. This determination is made based on the error correction flag.
[0098]
If the error has been corrected, the sync block is selected as a write sync block in step ST4, and the process ends in step ST5. When the sync block Sd reproduced immediately before in step ST7 is not selected as a writing block, when the sync block does not relate to the same macro block as the sync block Sd reproduced immediately before in step ST8, and step ST9 If the sync block has not been corrected, in step ST6, the sync block is not selected as a write sync block, and the process ends in step ST5.
[0099]
In addition, when writing the sync block Sd to the SDRAM 163, the input write buffer 165 adds a post sync error flag to the sync block Sd when the sync block Sh related to the same macro block as the sync block Sd cannot be written. To write to the SDRAM 163. In this situation, the regenerated sync block Sd is selected as the write sync block, but the regenerated sync block Sh is not related to the same macroblock as the sync block Sd, or error correction can be performed. This occurs when it is not selected as a write sync block.
[0100]
In this way, the post sync error flag is added to the sync block Sd and written to the SDRAM 163. The sync block Sh to be paired with the sync block Sd stored in the SDRAM 163 is the same macroblock as the sync block Sd. For example, the video decompression circuit 135 in the subsequent stage can prevent the use of the compressed encoded data included in the sync block Sh.
[0101]
Also, the input write buffer 165 writes the sync block to the SDRAM 163 when the audio data has been error-corrected by the C1 parity during the variable speed reproduction. In the present embodiment, the reproducing head Hr scans the magnetic tape 120 three times during one field which is a predetermined time. The sync block related to the audio data written in the SDRAM 163 is added with a scan number indicating the number of scans of the above three scans.
[0102]
Also in this case, each sync block is written at a predetermined address position in the memory space corresponding to 24 ECC blocks based on the track ID and sync block ID added thereto. In this case, in each field, writing is performed in a different memory space, and the memory space of the field after use is cleared. As a result, only the sync block reproduced in the predetermined field is written in the memory space corresponding to the 24 ECC blocks in which the sync block reproduced in the predetermined field is written.
[0103]
Returning to FIG. 15, the ECC decoder 134 supplies the data of each sync block in the 36 ECC blocks related to the video data read from the SDRAM 163 for each field to the video C2 decoder 167V described later. A video C2 read buffer 166V serving as a buffer, a video C2 decoder 167V that performs error correction processing using C2 parity in 36 ECC blocks for each field, and 36 fields corrected by the C2 decoder 167V for each field A video C2 write buffer 168V serving as a buffer for writing video data (compression encoded data) in the ECC block to the SDRAM 163 is provided. The portions of these buffers 166V and 168V and the C2 decoder 167V are used only during normal reproduction. That is, error correction processing using C2 parity is not performed during variable speed reproduction.
[0104]
The ECC decoder 134 is a video output buffer serving as a buffer for outputting compressed encoded data of each macro block based on 36 ECC blocks related to the video data stored in the SDRAM 163 for each field. 169V. In this case, the video output buffer 169V performs a depacking process, and acquires the compression encoded data of each macroblock from the corresponding sync blocks Sd and Sh.
[0105]
Note that the video output buffer 169V, when performing variable speed playback, if the post sync error flag is added to the sync block Sd for obtaining the compression encoded data of the predetermined macro block, the compression code of the predetermined macro block Among the encoded data, the compressed encoded data acquired from the sync block Sh is output with an error flag added. As a result, the video decompression circuit 135 at the subsequent stage can prevent erroneous use of the compressed and encoded data to which the error flag is added.
[0106]
In addition, the ECC decoder 134 reads out the audio C2 serving as a buffer for supplying the data of each sync block in the 24 ECC blocks related to the audio data read from the SDRAM 163 for each field to the audio C2 decoder 167A described later. A buffer 166A, an audio C2 decoder 167A that performs error correction processing using C2 parity in 24 ECC blocks for each field, and audio data in 24 ECC blocks corrected by the C2 decoder 167A, that is, 12 channels And an audio output buffer 169A serving as a buffer for outputting audio data for a minute.
[0107]
In this case, the C2 decoder 167A portion is used only during normal playback. That is, error correction processing using C2 parity is not performed during variable speed reproduction. At the time of variable speed reproduction, the audio data output from the buffer 166A is supplied to an audio output buffer 169A described later via the C2 decoder 167A.
[0108]
During variable speed playback, the buffer 166A samples audio data included in the selected sync block among the sync blocks stored in the memory space corresponding to the two ECC blocks of the SDRAM 163 for each channel for each field. Output only data in order. In this case, since the scan number is added to each sync block as described above, the sync block corresponding to the scan number corresponding to the most sync blocks is selected based on the scan number.
[0109]
In addition, the ECC decoder 134, when performing variable speed playback, for each field, missing samples by selectively using sync blocks as described above for the audio data of each channel supplied from the audio output buffer 169A. An interpolation circuit 170 that interpolates and outputs data is provided. The interpolation circuit 170 performs interpolation using at least the previous or subsequent valid sample data. For example, the effective sample data immediately before is used as interpolation data as it is. Further, for example, the effective sample data before and after is averaged to obtain interpolation data.
[0110]
During normal reproduction, the interpolation circuit 170 interpolates and outputs sample data that could not be error-corrected with respect to the audio data of each channel supplied from the audio output buffer 169A for each field. The audio data after interpolation processing by the interpolation circuit 170 is output as output audio data Aout.
[0111]
The operation of the ECC decoder 134 shown in FIG. 15 will be described. First, the operation during normal playback will be described.
[0112]
In the reproduction data DDc supplied from the decoding circuit 133, sync data is detected by the SYNC detection circuit 161, and then supplied to the C1 decoder 162. In the C1 decoder 162, error correction processing using C1 parity is performed on each sync block. Each sync block is output from the C1 decoder 162 with an error correction flag and ID indicating whether or not error correction has been added to the data string after the error correction processing.
[0113]
Each sync block output from the C1 decoder 162 is written to the SDRAM 163 via the input write buffer 165 and the SDRAM interface 164.
[0114]
In this case, each sync block related to the video data is written at a predetermined address position in the memory space corresponding to 36 ECC blocks for each field based on the track ID and sync block ID added thereto. As a result, 36 ECC blocks, each consisting of 126 sync blocks similar to those at the time of recording, are generated in the SDRAM 163.
[0115]
In this case, each sync block related to the audio data is written at a predetermined address position in the memory space corresponding to 24 ECC blocks for each field based on the track ID and sync block ID added thereto. As a result, 24 ECC blocks are generated in the SDRAM 163 for each field, each consisting of 16 sync blocks similar to those at the time of recording.
[0116]
For each field, the data of each sync block in the 36 ECC blocks related to the video data is read from the SDRAM 163 and supplied to the video C2 decoder 167V via the SDRAM interface 164 and the video C2 read buffer 166V. In the C2 decoder 167V, error correction processing is performed using C2 parity in 36 ECC blocks for each field. For each field, the video data (compressed encoded data) in the 36 ECC blocks corrected by the C2 decoder 167V is written to the SDRAM 163 via the video C2 write buffer 168V and the SDRAM interface 164.
[0117]
In addition, for each field, based on the 36 ECC blocks related to the video data stored in the SDRAM 163, the compressed encoded data of each macroblock is read out and output as output video data VDd via the output buffer 169V. Is output. In this case, the output buffer 169V performs a depacking process, and the compression encoded data of each macro block is acquired from the corresponding sync blocks Sd and Sh.
[0118]
For each field, the data of each sync block in the 24 ECC blocks related to the audio data is read from the SDRAM 163 and supplied to the audio C2 decoder 167A via the SDRAM interface 164 and the audio C2 read buffer 166A. In the C2 decoder 167A, error correction processing is performed using C2 parity in 24 ECC blocks for each field.
[0119]
For each field, the audio data in the 24 ECC blocks corrected by the C2 decoder 167A, that is, the audio data for 12 channels is supplied to the interpolation circuit 170 via the audio output buffer 169A, and error correction cannot be performed. Interpolation of sample data is performed. The audio data interpolated by the interpolation circuit 170 is output as output audio data Aout.
[0120]
Next, the operation during variable speed reproduction will be described.
In the reproduction data DDc supplied from the decoding circuit 133, sync data is detected by the SYNC detection circuit 161, and then supplied to the C1 decoder 162. In the C1 decoder 162, error correction processing using C1 parity is performed on each sync block. Each sync block is output from the C1 decoder 162 with an error correction flag and ID indicating whether or not error correction has been added to the data string after the error correction processing.
[0121]
Each sync block output from the C1 decoder 162 is written to the SDRAM 163 via the input write buffer 165 and the SDRAM interface 164.
[0122]
Hereinafter, the video data will be described first, and then the audio data will be described.
[0123]
The video data will be described. Of the sync blocks supplied from the C1 decoder 162, only the selected sync block is written into the SDRAM 163. That is, the sync block Sd is selected as a write sync block when error correction can be performed with C1 parity. As for the sync block Sh, the sync block Sd reproduced immediately before is selected as a writing block, the sync block Sh is related to the same macro block as the sync block Sd reproduced immediately before, and the sync block Sh When the block Sh can be error-corrected by the C1 parity, it is selected as a write sync block.
[0124]
In this case, each sync block is written at a predetermined address position in the memory space corresponding to 36 ECC blocks based on the track ID and sync block ID added thereto. In this case, writing is performed in the same memory space in each field, and the stored data is sequentially updated.
[0125]
In this case, the sync block Sd is written to the SDRAM 163. When the sync block Sh related to the same macroblock as the sync block Sd is not written to the SDRAM 163, a post sync error flag is added to the sync block Sd. It is written in the SDRAM 163.
[0126]
In addition, for each field, based on the 36 ECC blocks stored in the SDRAM 163, the compression encoded data of each macroblock is read and output via the SDRAM interface 164 and the video output buffer 169V. In this case, the compression encoded data of each macro block is acquired from the corresponding sync blocks Sd and Sh.
[0127]
Here, when a post sync error flag is added to the sync block Sd for obtaining the compressed encoded data of the predetermined macroblock, the sync block Sh of the compressed encoded data of the predetermined macroblock is included. The compressed encoded data obtained from the above is output with an error flag added. In this case, the sync block Sh that is paired with the sync block Sd on the SDRAM 163 does not actually contain the compressed encoded data related to the same macroblock. As a result, the video decompression circuit 135 at the subsequent stage can prevent erroneous use of the compressed encoded data to which the error flag is added, and can prevent deterioration in image quality due to mixing of the compressed encoded data of other blocks. .
[0128]
Audio data will be described. Of the sync blocks supplied from the C1 decoder 162, the sync block that has been error-corrected by the C1 parity is written into the SDRAM 163. In this case, the sync block written to the SDRAM 163 is added with a scan number indicating the number of scans of the above three scans.
[0129]
In this case, each sync block is written at a predetermined address position in the memory space corresponding to 24 ECC blocks based on the track ID and sync block ID added thereto. In this case, in each field, writing is performed in a different memory space, and the memory space of the field after use is cleared. As a result, only the sync block reproduced in the predetermined field is written in the memory space corresponding to the 24 ECC blocks corresponding to the predetermined field.
[0130]
Also, from the C2 read buffer 166A, for each field, the most sync block among the sync blocks stored in the memory space corresponding to the two ECC blocks of the SDRAM 163 is assigned to the corresponding scan number for each channel. A corresponding sync block is selected, and sample data of audio data included only in the sync block is sequentially output.
[0131]
Thus, for each field, sample data of audio data output for each channel from the buffer 166A is supplied to the interpolation circuit 170 via the audio C2 decoder 167A and the audio output buffer 169A. In the interpolation circuit 170, the missing sample data is interpolated with respect to the audio data of each channel by selectively using the sync block as described above. Then, the audio data after the interpolation processing by the interpolation circuit 170 is output as output audio data Aout.
[0132]
As described above, in the present embodiment, at the time of variable speed reproduction, the most sync blocks among the sync blocks related to the audio data reproduced by the three scans of the reproduction head Hp correspond to each field. The sync block corresponding to the scan number is used, and the missing sample data is interpolated using valid sample data at least before or after. Therefore, it is possible to reduce the possibility that sample data of different fields are mixed with audio data of one field, and it is possible to suppress deterioration in sound quality due to mixing of sample data of different predetermined times during variable speed reproduction.
[0133]
FIG. 17 shows an example of reproduction for one field during variable speed reproduction. In FIG. 17, an arrow SCN indicates a scanning locus of the reproducing head Hp. In FIG. 17, SP indicates a servo pilot for tracking servo.
[0134]
In this example, the recording part A1 (0-12F) of the first and second fields, in which the first half sync blocks of the ECC block of the block 0 and the block 12 including the 0-channel audio data are recorded, As indicated by the circles S1 and S2, scanning is performed in the first and second scans.
[0135]
In this case, for example, as shown in FIG. 18, from the recording part A1 (0-12F) in which the first half sync block is recorded, the first field sync block (broken line part) and the second field sync block are recorded. Only the sync block in the second field is reproduced from the recording unit A1 (0-12B) in which the (solid line portion) is reproduced and the sync block in the latter half is recorded.
[0136]
In this case, as shown in FIG. 19, the sample data in the ECC block of block 0 is composed of the sample data of the first field and the second field, and the sample data in the ECC block of block 12 is the second field. It consists only of sample data. In FIG. 19, the sample data of the first field is shown in italics.
[0137]
As described above, when all the sample data in the ECC blocks of the block 0 and the block 12 are used, the output audio data Aout is as shown in FIG. 20A, for example. In FIG. 20A, “Δ” indicates the level of the sample data in the first field, and “◯” indicates the level of the sample data in the second field. In this case, since sample data of different fields are mixed, the sound quality of the sound by the output audio data Aout is deteriorated.
[0138]
On the other hand, if the sync block corresponding to the scan number corresponding to the most sync block is used as in the above-described embodiment, the sample of the second field reproduced in the second scan is used. Only the data is used and the missing sample data is interpolated from the sample data in that second field. The output audio data Aout in this case is as shown in FIG. 20B, for example. In FIG. 20B, “◯” indicates the level of the sample data in the second field, and “X” indicates the level of the sample data interpolated from the preceding and following second sample data. In this case, since it consists only of the sample data of the second field, the sound quality of the sound by the output audio data Aout is improved.
[0139]
In the above-described embodiment, at the time of variable speed reproduction, for each field, among the sync blocks related to audio data reproduced by three scans of the reproduction head Hp, the most sync blocks correspond to the corresponding scan number. The one that uses the sync block is shown.
[0140]
Instead of using the sync block corresponding to the scan number corresponding to the most sync blocks, the sync block corresponding to the combination of the scan number and the segment number corresponding to the most sync blocks may be used. Also in this case, it is possible to reduce the possibility that sample data of different fields is mixed with audio data for one field, and to suppress deterioration of sound quality.
[0141]
In this case, the sync block corresponding to the segment number corresponding to the most sync blocks may be used. In that case, among the three scans in one field, a plurality of lines in which sync blocks for four fields in which the interval Da in the longitudinal direction of the scan position on the tape in the first and last scans is a segment number period are recorded. When the distance Db in the longitudinal direction on the tape occupied by the inclined track is exceeded, sync blocks of different fields may exist in sync blocks corresponding to the same segment number among the sync blocks reproduced in each field. As described above, the determination based on the combination of the segment number and the scan number can reduce the possibility that a sync block having a different field exists in the sync block to be used. FIG. 21 shows an outline of the interval Da and the distance Db.
[0142]
Also, instead of using the sync block corresponding to the corresponding scan number, the most sync block corresponds to the combination of the corresponding scan number and segment number when Da> Db. When sync blocks are used and Da ≦ Db, the sync block corresponding to the segment number corresponding to the most sync blocks may be used.
[0143]
When Da ≦ Db, there is no possibility that sync blocks of different fields exist in the sync blocks corresponding to the same segment number in the sync blocks reproduced in each field, and even if only the segment number is judged No problem. In this case, the number of sync blocks that can be used can be increased, the number of sample data to be interpolated can be reduced, and the sound quality can be improved.
[0144]
In the above embodiment, the predetermined time is one field, but the present invention is not limited to this. For example, the predetermined time may be a plurality of fields.
[0145]
In the above-described embodiment, the scanning is performed three times during a predetermined time, for example, one field, but the scanning may be performed twice or four times or more.
[0146]
In the embodiment described above, a segment number for identifying each field with a period of 4 fields is added to the sync block, but this period is not limited to 4 fields.
[0147]
【The invention's effect】
According to the present invention, a reproducing head performs N times (N is 2) every predetermined time on a tape on which a plurality of sync blocks corresponding to audio data for each predetermined time are recorded on one or a plurality of inclined tracks. (Integer above) is obtained by scanning and obtaining audio data for a predetermined time based on the sync block reproduced at each predetermined time. During variable speed reproduction, the reproduction head is scanned N times for each predetermined time. Of the sync blocks corresponding to the first to Nth scan numbers reproduced, the sync block corresponding to the scan number corresponding to the most sync blocks uses the missing sample data at least before or after Interpolation is performed using valid sample data to obtain audio data for a predetermined time. The sound quality of the deterioration due to the sample data is mixed can be suppressed.
[0148]
Further, according to the present invention, when a segment number for identifying each predetermined time is added to the sync block with a period of a plurality of predetermined times, the scan number and the segment corresponding to the most sync blocks are applicable. A sync block corresponding to a combination of numbers is used, and the interval Da in the longitudinal direction of the scan position on the tape in the first and last scans of N scans within a predetermined time is a plurality of predetermined times. When the distance Db in the longitudinal direction on the tape occupied by a plurality of inclined tracks on which a plurality of sync blocks are recorded is less likely to exist for different predetermined times in the used sync blocks, the different predetermined times It is possible to suppress deterioration of sound quality due to mixing of minute sample data.
[0149]
Further, according to the present invention, when a segment number for identifying each predetermined time is added to the sync block with a period of a plurality of predetermined times, when Da> Db, the largest number If the sync block uses a sync block corresponding to the combination of the corresponding scan number and segment number, and Da ≦ Db, the most sync blocks use the sync block corresponding to the corresponding segment number. If Da ≦ Db, the number of sync blocks that can be used can be increased, the number of sample data to be interpolated can be decreased, and the sound quality can be improved.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a recording / reproducing apparatus as an embodiment.
FIG. 2 is a diagram for explaining a recording format;
FIG. 3 is a diagram for explaining the arrangement of magnetic heads.
FIG. 4 is a diagram illustrating a configuration of an ECC block of video data.
FIG. 5 is a diagram illustrating a configuration of one sync block of video data.
FIG. 6 is a diagram for explaining the arrangement of sync blocks (video data) in 12 tracks.
FIG. 7 is a diagram illustrating an arrangement of C2 parity.
FIG. 8 is a block diagram showing a configuration of an ECC block of audio data.
FIG. 9 is a diagram illustrating a configuration of one sync block of audio data.
FIG. 10 is a diagram showing sample data of audio data arranged in ECC blocks of a block N and a block N + 12.
FIG. 11 is a diagram for explaining the arrangement of sync blocks (audio data) in 12 tracks.
FIG. 12 is a block diagram showing a configuration of an ECC encoder.
FIG. 13 is a diagram for explaining the relationship between a macro block and a sync block (video data);
FIG. 14 is a diagram showing an arrangement of two sync blocks related to the same macroblock.
FIG. 15 is a block diagram showing a configuration of an ECC decoder.
FIG. 16 is a flowchart showing a procedure of write sync block selection processing;
FIG. 17 is a diagram illustrating a reproduction example for one field at the time of variable speed reproduction;
FIG. 18 is a diagram illustrating a case where sync blocks of different fields are reproduced (on a track).
FIG. 19 is a diagram illustrating a case where sync blocks of different fields are reproduced (on an ECC block).
FIG. 20 is a diagram for explaining output audio data;
FIG. 21 shows a plurality of recorded sync blocks for 4 fields, which are the interval Da in the longitudinal direction of the scan position on the tape and the cycle of the segment number in the first and last scans among the three scans in one field. It is a figure which shows the outline | summary of the distance Db of the longitudinal direction on the tape which an inclined track | truck occupies.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 100 ... Recording / reproducing apparatus, 111V, 111A ... Input terminal, 112 ... Video compression circuit, 113 ... ECC encoder, 114 ... Recording amplifier, 120 ... Magnetic tape, 131 ... Reproduction amplifier 132 ... Equalization circuit 133 ... Decoding circuit 134 ... ECC decoder 135 ... Video decompression circuit 136V, 136A ... Output terminal 140 ... Rotating drum 151 ... SDRAM, 152 ... SDRAM interface, 153V ... Video input write buffer, 153A ... Audio input buffer, 154V ... Video C2 read buffer, 155V ... Video C2 encoder, 155A ... Audio C2 encoder, 156V ... Video C2 write buffer, 156A ... Dio C2 write buffer, 157 ... output buffer, 158 ... SYNC / ID addition circuit, 159 ... C1 encoder, 161 ... SYNC detection circuit, 162 ... C1 decoder, 163 ... SDRAM, 164 ... SDRAM interface, 165 ... input write buffer, 166V ... video C2 read buffer, 166A ... audio C2 read buffer, 167V ... video C2 decoder, 167A ... audio C2 decoder, 168V ... Video C2 write buffer, 169V ... Video output buffer, 169A ... Audio output buffer, 170 ... Interpolator

Claims (8)

Audio data composed of a plurality of sample data is divided every predetermined time, a plurality of sync blocks are generated from the audio data for each predetermined time, and a plurality of sync blocks corresponding to the audio data for each predetermined time are integrated. The reproducing head scans N times (N is an integer of 2 or more) on the tape recorded on one or a plurality of inclined tracks every predetermined time, and the sync block reproduced by the reproducing head at each predetermined time. A data reproduction method for obtaining audio data for a predetermined time based on each,
At the time of variable speed reproduction, the largest number of sync blocks among the sync blocks corresponding to the first to Nth scan numbers reproduced in the N scans of the read head for each predetermined time corresponds to the corresponding scan number. A data reproduction method characterized by using a corresponding sync block and interpolating missing sample data using at least previous or subsequent valid sample data to obtain audio data for a predetermined time. The audio data for the predetermined time is divided into one or a plurality of coding units, and error correction coding using a product code is performed for each of the divided coding units,
2. The data reproduction method according to claim 1, wherein the sync block is formed by adding an inner code parity to audio data or an outer code parity data string constituting an inner code calculation data sequence. A segment number for identifying each predetermined time is added to the sync block, with a plurality of predetermined time periods as a cycle.
Instead of using the sync block corresponding to the scan number corresponding to the most sync blocks above,
2. The data reproducing method according to claim 1, wherein a sync block corresponding to a combination of a scan number and a segment number corresponding to the largest number of sync blocks is used. A segment number for identifying each predetermined time is added to the sync block, with a plurality of predetermined time periods as a cycle.
Instead of using the sync block corresponding to the scan number corresponding to the most sync blocks above,
Of the N scans within the predetermined time during the variable speed playback, the interval in the longitudinal direction of the scan position on the tape in the first and last scans is Da, and a plurality of sync blocks for the predetermined time are recorded. When the distance in the longitudinal direction on the tape occupied by a plurality of inclined tracks is Db, if Da> Db, the sync number corresponding to the combination of the scan number and segment number corresponding to the most sync block is the most. 2. The data reproducing method according to claim 1, wherein when a block is used and Da ≦ Db, the sync block corresponding to the segment number corresponding to the most sync block is used. Audio data composed of a plurality of sample data is divided every predetermined time, a plurality of sync blocks are generated from the audio data for each predetermined time, and a plurality of sync blocks corresponding to the audio data for each predetermined time are integrated. The reproducing head scans N times (N is an integer of 2 or more) on the tape recorded on one or a plurality of inclined tracks at the predetermined time, and the sync block reproduced by the reproducing head is synchronized with the sync of the memory. A data reproducing device for writing audio data for a predetermined time based on a sync block written to the memory at each predetermined time, writing to an address position corresponding to the block,
Data writing means for adding to the sync block reproduced by the reproducing head at the time of variable speed reproduction, a scan number indicating the number of scans reproduced within the predetermined time, and writing to the memory;
When the audio data for the predetermined time is obtained based on the plurality of sync blocks written in the memory during the variable speed reproduction, the largest number of sync blocks among the plurality of sync blocks written in the memory And a data processing means for interpolating the missing sample data using at least the preceding or succeeding effective sample data, and using a sync block corresponding to the scan number. The audio data for the predetermined time is divided into one or a plurality of coding units, and error correction coding using a product code is performed for each of the divided coding units,
6. The data reproducing apparatus according to claim 5, wherein the sync block is formed by adding an inner code parity to audio data or an outer code parity data string constituting an inner code calculation data sequence. A segment number for identifying each predetermined time is added to the sync block, with a plurality of predetermined time periods as a cycle.
The data processing means is
Instead of using the sync block corresponding to the scan number corresponding to the most sync blocks above,
6. The data reproducing apparatus according to claim 5, wherein a sync block corresponding to a combination of a scan number and a segment number corresponding to the largest number of sync blocks is used. A segment number for identifying each predetermined time is added to the sync block, with a plurality of predetermined time periods as a cycle.
The data processing means is
Instead of using the sync block corresponding to the scan number corresponding to the most sync blocks above,
Of the N scans within the predetermined time during the variable speed playback, the interval in the longitudinal direction of the scan position on the tape in the first and last scans is Da, and a plurality of sync blocks for the predetermined time are recorded. When the distance in the longitudinal direction on the tape occupied by a plurality of inclined tracks is Db, if Da> Db, the sync number corresponding to the combination of the scan number and segment number corresponding to the most sync block is the most. 6. The data reproducing apparatus according to claim 5, wherein when a block is used and Da ≦ Db, the sync block corresponding to the segment number corresponding to the most sync block is used.

Images