JP4577617B2 - Recording / playback device - Google Patents

Description

  The present invention relates to a recording / reproducing apparatus for recording and reproducing DV audio data, an MPEG stream, and a subcode in a DV audio area, a DV video area, and a subcode area provided on each track of a tape, respectively.

  FIG. 7 shows a conventional apparatus for recording / reproducing on the tape T in the DV format shown in FIG. The video signal Video and the audio signal Audio are respectively recorded in DV format video data (hereinafter referred to as DV video data) and audio data (hereinafter referred to as DV video data) by a DV video encoder (DV VIDEO ENC) 1 and a DV audio encoder (DV AUDIO ENC) 2. Are recorded in a video area and an audio area of a DIF (digital interface) buffer 3. In addition, DV subcode information such as recording date and time code is recorded in the subcode area of the DIF buffer 3.

  The route output from the DIF buffer 3 includes a route recorded on the tape T and a route output to the outside via the IEEE1394 interface. When recording on the tape T, after the ECC 1/2 processing unit 4 performs ECC processing (ECC1) of the inner code and ECC processing (ECC2) of the outer code on the data of the DIF buffer 3, the tape format processing unit 5 is converted to a DV tape format as shown in FIG. On the other hand, when the tape T is reproduced and output to the outside via the IEEE1394 interface, the reproduction data of the tape T is sent to the DIF buffer 3 via the tape format processing unit 5 and the ECC1 / 2 processing unit 4, and the DIF buffer 3 is transferred to the DIF processing unit 6 and the IEEE 1394 block 7 and transmitted from the IEEE 1394 terminal 8 in the DIF format of IEC61883-2.

  FIG. 9 shows a conventional apparatus for recording and reproducing on the tape T in the HD1 mode format of the HDV standard shown in FIG. The video signal Video and the audio signal Audio are encoded into video data and audio data in the MPEG format by the MPEG video encoder (MPEG VIDEO ENC) 11 and the MPEG audio encoder (MPEG AUDIO ENC) 12, respectively. Each of them is time-division multiplexed by a subsequent multiplexed block (MUX) 13 to become one MPEG-TS data. The route output from the multiplexing block 13 includes a route recorded on the tape T and a route output to the outside via the IEEE1394 interface.

  When recording on the tape T, the MPEG-TS → DIF conversion unit 14 converts the MPEG-TS format to the DIF format. Hereinafter, a method for converting the MPEG-TS format into the DIF format will be described. The data unit (packet size) of MPEG-TS has a unit of 188 bytes, and this is called 1TS packet. On the other hand, since the DIF data unit is a 90-byte unit called a sync block, the data unit is converted. FIG. 11 shows the method, in which two MPEG-TS packets (188 bytes × 2) are divided into five DVC sync blocks, arranged, and added with a header and recorded. As described above, the conversion between MPEG-TS and DIF becomes possible by converting the data content of MPEG-TS into DIF without changing.

  The DIF data converted by the MPEG-TS → DIF conversion unit 14 is subjected to ECC processing (ECC3) in the time axis direction by the ECC3 processing unit 15 and then recorded in the video area of the DIF buffer 16. The audio signal for post-recording is converted into audio data in the DV format by a DV audio encoder (DV AUDIO ENC) 17 and recorded in the audio area of the DIF buffer 16. Also, DV subcode information such as recording date and time code is recorded in the subcode area of the DIF buffer 16. As described above, the audio area and subcode area of the DIF buffer 16 are the same as those in the conventional DV format signal processing. Next, after the ECC 1/2 processing unit 18 performs ECC processing (ECC1) and ECC processing (ECC2) of the outer code on the data in the DIF buffer 16, the tape format processing unit 19 as shown in FIG. The tape is converted into the HD1 mode tape format of the HDV standard and recorded on the tape T. On the other hand, when outputting to the outside via the IEEE 1394 interface, it is necessary to transmit the MPEG stream according to the IEC61883-4 standard, and therefore data is transmitted in the MPEG-TS format. That is, only the reproduction data of MPEG-TS on the tape T is passed to the tape format processing unit 19, ECC 1/2 processing unit 18, DIF buffer 16, ECC 3 processing unit 15, MPEG-TS → DIF conversion unit 14, and IEEE 1394 block 21. And transmitted from the IEEE 1394 terminal 22. Therefore, the DV audio area and subcode area data recorded on the tape T does not enter the MPEG-TS, and is not output from the IEEE 1394 terminal 22.

  Here, since the recording format shown in the DVC MPEG format (the HDV standard HD1 mode format) is the same as the conventional DV format and the physical format, the DV format and the HDV standard HD1 mode MPEG format 2 in the same system are used. A mode can be realized. In addition, IEEE 1394 terminal 22 is provided for digital data transmission, and data transmission with an external device is possible. When playing back a tape recorded in DV format, it is in IEC61883-2 DIF format and HDV standard When playing back a tape recorded in the HD1 mode format, it is transmitted over IEEE 1394 in the MPEG-TS format of IEC61883-4.

The recording method shown in the HDV mode HD1 format format multiplexes MPEG video data and MPEG audio data in the TS format to the DV video area used in the conventional DV format with respect to the physical area on the tape. However, the DV audio area is independent as a DVC audio data recording area, and DV audio data can be recorded and reproduced separately from MPEG data. For this reason, it is possible to easily realize an after-recording function for adding BGM or adding narration to a tape that has already been shot using a DV audio area (see, for example, Patent Document 1 below).
JP 2004-201168 A (abstract)

  The recording method shown in the HD1 mode format of the HDV standard is a method that can record not only MPEG data but also DV audio data independently. Therefore, after recording such as adding BGM to a recorded tape or adding narration. Functions can be realized easily. However, when such a tape is transmitted to the outside via an IEEE 1394 terminal, MPEG data is recorded in the HD1 mode format of the HDV standard, so the transmission method on IEEE 1394 is recorded in the DV video area. Therefore, the DV audio data after-recording on the tape cannot be transmitted, and as a result, the after-recording audio cannot be transmitted to the outside.

  Even in the HDV HD1 mode format mode, subcode data such as recording date and time code is recorded on the tape in the same format as the DV mode, but in the case of the MPEG-TS format. Since subcode data is not transmitted, even when a tape recorded in MPEG format is dubbed / copied via IEEE 1394, the recording date / time information cannot be copied, and complete copy / dubbing including data other than MPEG is performed. I could not.

  An object of the present invention is to provide a recording / reproducing apparatus capable of transferring data other than MPEG-TS recorded on a tape in the MPEG format to the outside.

In order to achieve the above object, the present invention compresses video data and first audio data, respectively, and MPEG-TS which is data obtained by time-division multiplexing the compressed video data and the first audio data. Is converted into data by a method based on the HDV mode of the HDV standard based on the DV standard, and recorded in a DV video area provided in each track of the DV tape,
Second audio data different from the first audio data recorded as the MPEG-TS in the DV video area is recorded in a DV audio area provided in each track of the DV tape,
Subcode data, which is additional data including at least time information recorded on the MPEG-TS, is recorded in a DV subcode area provided in each track of the DV tape;
In the recording / reproducing apparatus having a function of reproducing the recorded MPEG-TS, the second audio data, and the subcode data, and outputting the reproduced data to the outside as a digital signal,
For the MPEG-TS, the second audio data, and the subcode data read from the DV video area, the DV audio area, and the DV subcode area, inner codes and outer codes based on the DV standard are used. Error correction means for performing error correction;
The MPEG-TS, the second audio data, and the subcode data read from the DV video area, the DV audio area, and the DV subcode area, respectively, are converted into an IEC61883-2 format that is a digital interface standard. Set in the video DIF area, audio DIF area and subcode DIF area of the DIF packet according to the structure,
And among the correction results corrected by the error correction means, the error correction result of the inner code is set in the DBN area of the DIF packet,
Further, by setting the error correction result of the outer code in the reserved area of the header section of the DIF packet, a DIF packet having a new format based on the IEC61883-2 format is generated and output to the outside as a DIF packet Means,
It is characterized by having.

  According to the present invention, DV audio data, MPEG stream and subcode respectively read from the DV audio area, DV video area and subcode area of the tape are subjected to error correction of inner code and outer code, and DV audio area, The DV audio data, MPEG stream, subcode and correction processing result read from the DV video area and subcode area are placed in the DIF packet and output to the outside in the DIF format, so they are recorded on the tape in the MPEG format. Data other than MPEG-TS can be transferred to the outside.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of a recording / reproducing apparatus according to the present invention, FIG. 2 is an explanatory diagram showing a data structure of a DIF sequence, FIG. 3 is an explanatory diagram showing a result of inner code correction processing, and FIG. FIG. 5 is an explanatory diagram showing the data structure of the IEEE 1394 CIP header, and FIG. 6 is an explanatory diagram showing the FMT in FIG. 5 in detail.

  In FIG. 1, the signal processing route of the video signal Video and the audio signal Audio, the audio signal for post-recording, and the route for recording the signal such as the subcode are the same as the HDV standard HD1 mode format method of FIG. However, in this embodiment, in order to be able to transmit DV audio data and subcode data in addition to MPEG data from the IEEE 1394 terminal 32, MPEG data recorded in the video area of the DIF buffer 16 is converted to DIF format. The data is taken out and transferred to the Pro-HD processing block 30. This is because the MPEG-TS format and the DIF format can be converted into each other, and the DIF format is suitable for transmission in the format of IEC61883-2. The DV audio and subcode data in the DIF buffer 16 are also transferred to the Pro-HD processing block 30 in the same manner as the DV format. Furthermore, the ECC 1/2 processing result is also transferred to the Pro-HD processing block 30.

  Furthermore, when the data processed in this way is transmitted via the IEEE 1394 block 31, it is neither the format of IEC61883-2 (DIF) nor IEC61883-4 (MPEG-TS). , Pro-HDV format). In the Pro-HDV format transmission method, the MPEG-TS → DIF conversion and ECC3 processing, which has been performed in the HD1 mode format of the conventional HDV standard, is performed on the receiver side. By adding the ECC1 / 2 flag information to the transmission data without breaking the DIF format, HDV format processing on the receiver side can be realized.

  Here, the data structure of the DIF stream will be described. One frame of the 525-30 system is composed of 10 DIF sequences, and one frame of the 625-25 system is composed of 12 DIF sequences. As shown in FIG. 2, one DIF sequence is composed of 150 DIF blocks each having 80 bytes. Specifically, the header section of one header DIF block H0 and the sub-codes of two subcode DIF blocks SC0 and SC1. The video section includes a code section, video auxiliary sections of three video auxiliary DIF blocks VA0, VA1, and VA2, audio sections of nine audio DIF blocks A0 to A8, and 135 video DIF blocks V0 to V134. Therefore, in the Pro-HD processing block 30, the subcode, DV audio data (PCM data), and MPEG-TS reproduced from the tape T are converted into subcode DIF blocks SC0 and SC1, audio DIF blocks A0 to A8, and a video DIF block, respectively. Arranged at V0 to V134.

  One DIF block is composed of a 3-byte DIF block ID and a 77-byte data portion. As shown in FIG. 3A, the DIF block ID of 3 bytes (ID0, ID1, ID2) includes a DIF block type (SCT2 to SCT0), a DIF sequence number (DSeq3 to DSeq0), and a DIF block number (DBN7). To DBN0).

  A method of adding ECC 1/2 flag information will be described. First, the 8-bit (ID2) DIF block number (DBN7˜) in the DIF block IDs (ID0, ID1, ID2) of the video auxiliary DIF blocks VA0, VA1, VA2, audio DIF blocks A0 to A8 and video DIF blocks V0 to V134. Instead of DBN0), the results Iflag3 to Iflag0 of the 4-bit inner code correction process (ECC1) are stored as shown in FIG. The detailed contents of the correction results Iflag3 to Iflag0 are shown in FIG. Further, as shown in FIG. 4, since the positions of the 48th to 59th bytes and the 68th to 79th bytes of the header DIF block H0 are reserved areas (normally all 1), this of the header DIF block H0 with DIF sequence number = N The result of the outer code correction process (ECC2) of track = N (audio ECC2 flag aflag, video ECC2 flag vfrag) is stored in the reserved area.

  Furthermore, when the data processed in this way is transmitted via IEEE 1394, it is not one of the formats of IEC61883-2 (DIF) or IEC61883-4 (MPEG-TS), so a new transmission format (Pro-HDV Format) is defined in the header of the IEEE 1394 packet. Here, as shown in FIG. 5, the IEEE 1394 CIP header is composed of 4 bytes (Quadlet) × 2 and includes a source node ID (ID), a data block size (DBS), a fraction number (FN), a Quadlet padding count ( QPC), source packet header (SPH), data block continuity counter (DBC), format ID (FMT), etc. As shown in FIG. 6, FMT is 0x00 for DVCR and MPEG2-TS. Is defined as 0x20, and Free = 0x1E is defined as free (vendor unique). Therefore, by setting Free = 0x1E and specifying the new mode (Pro-HDV vendor unique format), and clearly indicating that the transmission mode is the new mode, the receiver side sees the value of this FMT to determine the transmission mode. The received data processing is changed to the Pro-HDV mode.

FIG. 1 is a block diagram showing an embodiment of a recording / reproducing apparatus according to the present invention. It is explanatory drawing which shows the data structure of a DIF sequence. It is explanatory drawing which shows the correction process result of an inner code. It is explanatory drawing which shows the correction process result of an outer code. It is explanatory drawing which shows the data structure of the CIP header of IEEE1394. It is explanatory drawing which shows FMT of FIG. 5 in detail. 1 is a block diagram showing an embodiment of a DV format recording / reproducing apparatus. FIG. It is explanatory drawing which shows a DV tape format. 1 is a block diagram showing an embodiment of a recording / reproducing apparatus in an HDV mode HD1 mode format. FIG. It is explanatory drawing which shows the tape format of HD1 mode of a HDV specification. It is explanatory drawing which shows the process of MPEG-TS-> DIF conversion.

Explanation of symbols

11 MPEG video encoder (MPEG VIDEO ENC)
12 MPEG audio encoder (MPEG AUDIO ENC)
13 Multiplexed block (MUX)
14 MPEG-TS → DIF conversion unit 15 ECC3 processing unit 16 DIF buffer 17 DV audio encoder (DV AUDIO ENC)
18 ECC1 / 2 processing unit 19 Tape format processing unit 30 Pro-HD processing block

Claims (1)

MPEG-TS, which is data obtained by compressing video data and first audio data, and time-division-multiplexing the compressed video data and the first audio data, is based on the DVV standard. Data is converted by a method based on the HD1 mode and recorded in a DV video area provided on each track of the DV tape.
Second audio data different from the first audio data recorded as the MPEG-TS in the DV video area is recorded in a DV audio area provided in each track of the DV tape,
Subcode data, which is additional data including at least time information recorded on the MPEG-TS, is recorded in a DV subcode area provided in each track of the DV tape, and the recorded MPEG-TS, the second In a recording / reproducing apparatus having a function of reproducing the audio data and the subcode data and outputting the reproduced data to the outside as a digital signal,
For the MPEG-TS, the second audio data, and the subcode data read from the DV video area, the DV audio area, and the DV subcode area, inner codes and outer codes based on the DV standard are used. Error correction means for performing error correction;
The MPEG-TS, the second audio data, and the subcode data read from the DV video area, the DV audio area, and the DV subcode area, respectively, are converted into an IEC61883-2 format that is a digital interface standard. Set in the video DIF area, audio DIF area and subcode DIF area of the DIF packet according to the structure,
And among the correction results corrected by the error correction means, the error correction result of the inner code is the D
Set in the DBN area of the IF packet,
Further, by setting the error correction result of the outer code in the reserved area of the header section of the DIF packet, a DIF packet having a new format based on the IEC61883-2 format is generated and output to the outside as a DIF packet Means,
A recording / reproducing apparatus comprising:

Images