KR970006702B1 - A method for writing time code signal of digital v.t.r. - Google Patents

Abstract

None.

Description

Time code signal recording method in digital VTR

1 is a diagram showing an example of allocation of an SMPTE time code signal and its user area.

2 shows an example of a recording track pattern of a digital VTR.

3 shows an audio sector arrangement of audio segments.

4 is a data configuration diagram of an audio sector.

* Explanation of symbols for main parts of the drawings

Audio sector: 1'0, 1'E, 2'0, 2'E, 3'0, 3'E, 4'0, 4'E

TV ₁ and TV ₂ : video half track section

TA: Audio track portion USER 0 to 15: User area

The present invention relates to a SMPTE time code signal recording method in a digital VTR of the present invention.

According to the present invention, audio data of unit time is recorded in SMPTE time code signals in a so-called 4: 2: 2 digital VTR in which the middle portion of the rotating magnetic head scanning direction on a tape is an audio track portion composed of a plurality of audio sectors. The same contents are recorded in m (mn) audio sectors of the n audio sector layers, and the time code portion and the user bit portion of the SMPTE time coat signal are separately recorded in the audio sectors. In this case, the time code can be extracted even at high speed reproduction and the time code part and the user bit part are recorded separately, so that the time code and the user bit can be easily processed, and the rewriting is relatively easy.

In the analog VTR, the time code signal is recorded at one end of the magnetic tape width direction by the head along the rectangular direction, and at the same time, it is recorded on the inclined track while overlapping in one or two horizontal sections within the video signal vertical blanking period. Then, during playback, the time code signal on the magnetic tape side is read during normal speed, low speed and high speed, and the time code signal is read from the signal from the inclined track during ultra-low speed and still picture playback at the time of stop. In addition, regardless of the traveling speed and direction of travel of the magnetic tape, continuous time code data is obtained (see Publication No. 58-23993).

However, since digital video signals are preshuffled when recording digital video signals, even if the time code signals are superimposed in the vertical blanking period, they must be deshuffled correctly for reading. Therefore, in the digital VTR, the time code signal is not recorded in the video track, and the time code signal is only recorded in the rectangular direction at one end of the magnetic tape width direction by the fixed head. For this reason, in digital VTRs, time code signals cannot be obtained during ultra-low speed playback or still playback.

In light of this, Applicant has first identified as A 61-81613 (Patent 62-237876) an area separate from the video track in the middle part of the rotational head scanning direction on a tape in a so-called 4: 2: 2 digital VTR. A method of recording a time code signal in a plurality of user sectors of an audio sector of an audio track portion which is formed in the form of an eoss.

The SMPTE time code signal has a time code part and a user bit part, but the method of recording the time code signal in the proposed audio sector is recorded without distinguishing the two.

However, when editing with digital VTR or rewriting the information of the time code signal user bit part, it is necessary to reproduce all of the user area to which the time code signal of the audio sector is assigned, and decode it once, and the processing is complicated. At the same time, there is a problem that it takes time to rewrite the time code data.

In the present invention, the middle portion of the rotational magnetic head scanning direction on a tape is formed of a plurality of slanted tracks, each of which is a video track portion, before and after an audio track portion composed of a plurality of audio sectors. In the digital VTR for recording the digital audio signal on the tape, the time code portion and the user bit portion of the SMPTE time code signal are separately recorded in the plurality of user regions of the audio sector, and at the same time, audio data for unit time is recorded. SMPTE time code signals having the same contents are recorded in m (mn) audio sectors of the n audio sector layers included in the plurality of tracks.

SMPTE time codes of the same content are superimposed on a plurality of audio sectors located at the center of the inclined track. This makes it possible to reliably extract the time code even during shift playback.

In addition, the time code portion and the user bit portion of the SMPTE time code signal are separated and recorded in a separate user area in the audio sector. Therefore, various processing of each of the time code portion and the user bit portion can be easily performed.

An example of the application of the present invention to a 4: 2: 2 digital VTR for recording a component digital signal will be described below.

2 is a magnetic tape recording track pattern formed of this digital VTR (only a recording track formed of a rotating head is shown).

As is known, for a tape scan of one head, an audio track portion TA is formed in the middle of the tape scan, and video half track portions TV ₁ and TV ₂ are formed before and after this audio track portion TA.

The pair of rotary heads H ₁ and H ₂ are shifted substantially in the pitch of the track in the direction of the axis of rotation so that they are fixed at approximately the same rotational angular position and at a different position from the head H ₁ , H 180, relative to the pair of rotary heads H ₁ and H ₂ . A pair of rotary heads H ₃ and H ₄ are fixed in the same relationship as H _2, and the recording track of FIG. 2 is formed by these four rotary heads.

Thus, _two inclined tracks of the track portions TV ₁ , TV ₂ and TA are formed almost simultaneously.

In the case of recording a 525/60 video signal, as shown in FIG. 2, a digital video signal for one field starts recording on the audio half track portion TV ₂ , and 10 half video tracks TV ₁ and half Video tracks TV ₂ are recorded as 10 total 20 Haat video tracks. In the audio track portion TA in the meantime, four channels of digital audio signals related to one video signal are recorded. In the case of the video signal of the 625/60 system, one field is recorded in 12 slope tracks.

In this case, a signal recorded on a pair of adjacent half track portions TV ₂ and TV ₂ shown in FIG. 2 by dotted dots is called one video segment, and this one video segment contains 50 horizontal lines of information.

In Fig. 2, a signal recorded in four adjacent audio track portions TA indicated by diagonal lines is called one audio segment, and contains information for each unit of time of the four-channel audio signal.

3 is a diagram for explaining one audio segment.

As shown in the figure, four audio sectors (sector 0, sector 1, sector 2, sector 3 in the scanning direction) are formed in each audio track portion TA. Thus, one audio segment consists of 16 sectors.

In the sector 0 of the four audio track portions TA, digital audio signals 1'E, 2'E, 3'E, and 4'E of even samples of the first to fourth channels are recorded, respectively. do. In sector 1 of the four audio track portions TA, the digital audio signals 4'0, (1'0), (2'0) and (3'0) of odd samples of the fourth, first to third channels, respectively. Is recorded. The four audio track portion TA sector 2 has digital audio signals (3'E), (4'E), (1'E), and (2 ') of even samples of third, fourth, first, and second channels, respectively. E) is recorded. The four audio track parts TA sector 3 have digital audio signals 2'0, 3'0, 4'0, and 1 'of odd samples of the second, third, fourth, and first channels, respectively. 0) is recorded. In addition, four audio track portions TA sector 0, 1 and sector 2, 3 of one audio segment each contain the same data in different arrangements.

FIG. 4 shows the data configuration of the audio sector described in FIG. This is a data structure of sectors in which even samples are recorded, but the same is true in sectors in which odd samples are recorded.

In other words, the audio sector has a word data area (WORD 0, 1, 2, ...), an error correction data area (PV 0, 1, 2), and eight user areas USER 0, 2, 4, 6, 8 of 1 byte each. , 10, 12, 14, and other data areas. Therefore, one audio sector is in the user area of 8 bytes in total. In the odd-numbered audio sector, there are eight user areas USER 1, 3, 5, 7, 9, 11, 13 and 15 of 1 byte, respectively.

However, the SMPTE time code signal is shown on the right side of Fig. 1 as the hour (1 and 10 digits), minute (1 and 10 digits), seconds (1 and 10 digits), and frame (1 A time code part indicating information of a digit and ten digits) and a user bit part which is allocated as a bit after each information with at least the same number of bits as each piece of information, and is composed of a total of 64 bits = 8 bytes.

On the other hand, as shown in FIG. 4, one audio sector user area has 8 bytes, and one SMPTE time code can be allocated to one audio sector.

In this case, in the present invention, the first user region USER 0,2,4,6,8,10,12,14 or USER 1,3,5,7,9,11,13,15 of the eight audio sectors is used. As shown in the left side of the figure, the time code part and the user bit part of the SMPTE time code signal are separately allocated.

That is, one-byte information of frame 1 and 10 digits of the frame code part is stored in the user area USER 0 (USER 1 in odd-sample sectors) of the audio sector, and one-byte information of the first 1 and 10 digits. Is stored in the user sector USER 2 (USER 3 in the odd sample sector) of the audio sector, and the one-byte information of the one and ten digits in the audio sector is stored in the user area USER 4 (USER 5 in the odd sample sector) of the audio sector. The one-byte information of one digit and ten digits of time is allocated to the user area USER 6 (USER 7 in odd-sample sectors) of the audio sector, respectively.

Similarly, the information corresponding to the frame of the SMPTE time code signal user bit portion is in the audio sector user area USER 8 (USER 9 in odd sample sectors), and the information corresponding to the seconds in the user bit portion is user area USER 10 (odd number). In the sample sector, the information corresponding to USER 11), the minute of the user bit portion is stored in the user area USER 12 (USER 13 in the odd sample sector), and the information corresponding to the time of the user bit portion is stored in the user area USER. 14 (USER 15 in odd sample sectors), respectively.

In this example, in FIG. 3 of one audio segment, 12 which is indicated by adding diagonal lines other than four one-channel audio sectors 1'E, 1'0, 1'E, and 1'0. The same SMPTE time code is assigned to the user area of the sector and recorded. The reason that the time code is not recorded in the audio sector user area of the first channel is for leaving the use of the audio sector as an original user area. In this case, four audio sectors of the first channel are included in one audio track of each of the four audio tracks constituting one audio segment and are suitable for use as an original user area. In addition, since the user area can be processed in the processing of audio data of a single channel, the recording, reproduction, and rewriting process can be facilitated. Therefore, the user area of the powder channel sector other than the first channel audio sector may be left for the original usage without time code.

In addition, the four audio sectors 1'E, 1'0, 1'E, and 1'0 for the first channel are arranged side by side in a straight line. It is conceivable that the state scans only the audio sector for the first channel, and the time code cannot be extracted from the reproduction output of the head. However, as described above, the two rotating heads are fixed at the position where the track pitch is shifted in the direction of the rotation axis, and the two heads scan the tape, so that the other head scans the separate scanning positions on the tape even if one head is scanned as described above. Therefore, the time code can always be extracted from the playback output of the other head.

The reading of the SMPTE time code signal recorded as above will be described as follows.

In the normal speed playback, the same time code signal is played 60 times per frame, so that one time code signal can be selected. In this case, an error is detected for each user area of the audio sector, and an error flag is set for an error, and an audio sector without an error flag is found in all eight user areas, and the time code signal of the sector is detected. We can adopt as right thing.

Also in the case of shift reproduction other than the normal speed reproduction, when a plurality of the same time codes are obtained from 20 inclined tracks for one frame, the time code of the sector selected as above is adopted.

In addition, in high-speed playback such as tracing 20 scan tracks per frame in one scan, time code is recorded in 12 sectors of 16 sectors of one audio segment, and the time code must be extracted because the content is the same in one frame section. can do.

In addition, the time code recorded along the rectangular direction at the end of the tape width direction may not correspond to the data read from the memory in the digital VTR at the time of shift reproduction. The time code taken out of the signal can be stored in the buffer memory along with the playback digital video signal from its rotating head, so that the temporal correspondence between the playback video signal and the time code can always be taken.

According to the present invention, since the time code portion and the user bit portion of the SMPTE time code signal are divided and recorded in separate user areas in the audio sector, it is easy to separate the processing of the time code portion and the user bit portion. It is easy to write and rewrite each of the code part and the user bit part. Also during playback, processing of the time code portion and user bit portion is simplified.

In addition, as in the example of the drawing, when the information of hours, minutes, seconds, and frames is allocated and recorded in a separate user area, processing for each information can be facilitated.

In addition, since the time code signal has the same content recorded in a sector other than the audio sector using the user area as the original user among the audio sectors of one audio segment in the center of the scan track, the time code signal is surely time coded even at high speed playback. Can be obtained.

In this case, if the audio sector which originally uses the user area as the user is a sector in which audio data of the same channel is recorded as in the example of the figure, recording of the user area is accompanied by recording and reproduction of the audio data of the channel. Since reproduction can be performed, this original user data processing is also easy.

Claims (1)

The middle portion in the scanning direction of the rotating magnetic head on the tape includes an audio track portion composed of a plurality of audio sectors, and a plurality of inclined tracks formed before and after the video track portion for each field of the video signal to generate a digital video signal and a digital audio signal. In a digital VTR recorded on a tape, a plurality of tracks in which time code portions and user bit portions of an SMPTE time code signal are separately recorded in a plurality of user areas of the audio sector, and at the same time, audio data for unit time is recorded. A time code signal recording method using a digital VTR in which an SMPTE time code signal having the same content is recorded in m audio sectors among the n audio sectors included in.

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