KR940006727B1 - Recording and reproducing apparatus - Google Patents

Abstract

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Description

Recorder

1 is a configuration diagram of an example of the present invention.

2 is an explanatory diagram for an example of the present invention.

3 and 4 are explanatory diagrams for another example.

5 is an explanatory diagram of a conventional apparatus.

* Explanation of symbols for main parts of the drawings

1: input terminal 2: time base compression circuit

3,4: Sync separation circuit 4,16: PLL

5,17: control circuit 6: horizontal synchronous and burst signal generating circuit

7: switch circuit 8: recording circuit

9: recording playback switching switch 10: rotary head

11 tape 12 regeneration circuit

13 time axis extension circuit 15 burst gate circuit

16: time base correction circuit 19: output terminal

The present invention relates to an apparatus for recording and reproducing a video signal in which a band is transmitted through a Hancheong transmission line.

The present invention relates to recording and reproducing of a video signal transmitted over a band-limited transmission path, by adding a new horizontal synchronization signal and burst signal, which are easily detected at the time of recording, and by the horizontal synchronization signal and burst signal at the time of reproduction. The new axis correction of the signal is performed to obtain a stable good video signal on the time axis.

For example, the luminance signal Y as shown in the 5A FIG, B, in the case where the chroma signals of the two systems C _1, C _2, as shown in C, the chroma signal C _1, for each horizontal period, the C ₂ in order line The time axis compression is performed in the horizontal period of the luminance signal Y, and transmitted as a single synthesized signal as shown in the same D drawing.

On the other hand, when there is a limitation in the band of the signal transmission path, in order to effectively use the band in the image signal (luminance signal Y and chroma signal C), the synchronization signal (horizontal synchronization signal HD) has the same polarity as the image signal. The insertion is performed as shown in the drawing, and as shown in the drawing described above. In this case, detection separation of the synchronization signal cannot be performed by level detection as in the conventional NTSC signal, but a frame synchronization of a specific pattern is formed for each frame of the video signal, and this pattern is detected, thereby detecting it. Based on the frame synchronization, the horizontal synchronization signal HD is detected by time typing.

For this reason, when recording and reproducing the composite signal (TC ₁ signal) into which the synchronization signal is inserted, if there is a time axis variation (jitter) in the reproduction signal, it becomes difficult to detect the horizontal synchronization signal HD. The time base extension of the chroma signal can be performed based on the synchronization signal HD.

In other words, even if the time axis correction (TBC) is performed, only the frame synchronization can be used as a reference among the reproduction signals. Thus, the time axis correction is extremely difficult and the complete correction is impossible.

In addition, in order to require the above-described procedure for the detection separation of the synchronization signal, it takes a long time until the synchronization signal is detected. I need time.

Conventionally, when recording and reproducing a composite signal as described above with a video tape recorder, there is a problem that a good reproduction signal for jitter is not obtained.

The present invention records and reproduces a horizontal synchronous signal HD having the same polarity as the image signal and a video signal provided between the horizontal periods of the image signal, so that the second signal having a reverse polarity to the image signal is recorded in the video signal during recording. When the horizontal synchronization signal RH and the burst signal RB are added, recording is performed, and during reproduction, the second horizontal synchronization signal is extracted as level detection.

The burst signal is extracted as the extracted second horizontal synchronization signal, and the extracted burst signal is used to remove time-base errors of the image signal and the horizontal synchronization signal (TBC 18), and playback of the video signal is performed. A recording and reproducing apparatus is performed.

According to this apparatus, a second synchronization signal and a burst signal, which are easy to be separated at the time of recording, are added, and these are separated at the time of reproduction and time axis correction or the like is performed, so that a good video signal can be easily reproduced.

1 shows the configuration of a recording / playback apparatus. In this figure, at the time of recording, the input terminal 1 is supplied with a TCI signal as shown in the waveform A diagram of FIG. While this signal is supplied to the time base compression circuit 2, this signal is supplied to the synchronization separation circuit 3 so that the synchronization signal is separated in the above-described order. This separated synchronization signal is supplied to the PLL 4 to form a clock signal of a predetermined frequency. The clock signal and the synchronization signal are supplied to the control circuit 5 to form corresponding timings for each horizontal period including the horizontal synchronization signal HD, the chroma signal C, and the luminance signal Y. This tie signal is supplied to the time base compression circuit 2 so that this one horizontal period is compressed at a predetermined ratio as shown in the waveform B diagram. In addition, the timing signal from the control circuit 5 is supplied to the generating circuit 6, and the image signal (chroma signal C and the luminance signal) is provided between the gaps in which one horizontal period is compressed as shown in the waveform B diagram. A second horizontal synchronization signal RH of reverse polarity to Y) and a burst signal RB of a predetermined frequency and phase are generated. The generated signal and the signal in the compression circuit 2 are switched from the switch circuit 7 to the timing in the control circuit 5, and a recording signal as shown in the waveform B diagram is formed. This signal is supplied to the rotating head 10 through the recording circuit 8 and the recording / reproducing switching switch 9, and recorded on the tape 11.

At the time of reproduction, the signal reproduced by the rotating head 10 on the tape 11 is drawn out through the switch 9 and the reproduction circuit 12. This reproduction signal is equivalent to the signal of waveform B, but contains jitter components. This signal is supplied to the time base extension circuit 13, and this signal is supplied to the separation circuit 14 and the burst gate circuit 15 of the second horizontal synchronization signal RH. This separated synchronization signal is supplied to the burst gate circuit 15 to extract the burst signal RB. The extracted burst signal RB is supplied to the PLL 16 to form a clock signal having a predetermined frequency including the jitter component described above. The clock signal and the synchronization signal are supplied to the control circuit 17 to form a timing signal corresponding to each time period of time axis compression. This timing signal is supplied to the time extension circuit 13 so that this one horizontal period is extended to the original length as shown in the waveform C diagram. The signals of each extended horizontal period are successively supplied to the time axis correction circuit (TBC) 18, and the clock signal from the PLL 16 is supplied to the TBC 18. As a result, a TCI signal as shown in the waveform C diagram from which the jitter component is removed is formed, and the signal is output to the output terminal 19.

Therefore, in this apparatus, by adding an image signal, a second horizontal synchronizing signal and a burst signal having reverse polarity at the time of recording, the synchronization isolating circuit 14 first makes it very easy and short time to be synchronized by the level detection or the like during reproduction. Signal DML separation can be performed. In the burst gate circuit 15, since the burst signal exists near the synchronization signal, the burst signal can be extracted easily and accurately by delaying the synchronization signal. Again, in the PLL 16, the clock signal is easily and satisfactorily formed by using the burst signal.

In this way, the recording and reproducing of the TCI signal is performed, but according to the apparatus described above, a second synchronization signal and a burst signal, which are easy to be separated at the time of recording, are added, and at the time of reproduction, the time axis correction is performed. It is possible to reproduce a good video signal.

In the above apparatus, the second synchronization signal and the burst signal may be added by inserting the image signal between the gaps formed by time-base compression. However, the second synchronization signal and the burst signal may be added in another way. It may be inserted.

In the first embodiment, however, the time-base compression of the signal is performed at the time of recording, so that the frequency band of the signal is wider, and a wider band is required as the video tape recorder. On the other hand, in the second embodiment described below, the recording and reproducing is performed as a narrower video tape recorder. That is, in this example, it is applied to the case where the video tape recorder is narrowed by recording and reproducing by dividing the signal into two systems every one horizontal period.

In FIG. 3, at the time of recording, the TCI signal supplied to the input terminal 31 is supplied to the AD converter circuit 32 to be digitalized at a sampling frequency of, for example, 600fh (fh is a horizontal frequency). This digitalized signal is supplied to the channel division and time axis extension circuit 34 through the Apache compensation circuit 33. The digitalized signal is also supplied to the PLL clock generation circuit 35, and the clock signal here is supplied to the timing control circuit 36.

As a result, in the decompression circuit 34, for example, the signal shown in the waveform A diagram of FIG. 4 is extended by, for example, (20/11) times at intervals of one horizontal period, so that the waveform B diagram and the waveform C diagram are shown. As in two channels, a signal provided between gaps is formed between each horizontal period. In this channel, a delay circuit 37 having a time + 0.5H (H is a horizontal period) of the distance between the two heads is provided in the channel on the side of the signal recorded by the head on the preceding side of the two heads described later. As a result, the horizontal period adjacent to the adjacent portion of the track on the tape is recorded.

The digital burst signal RB is supplied from the generating circuit 38 and inserted in these signals, respectively. Again, the installed signals of these burst signals are supplied to the DA conversion circuits 39a and 39b, respectively, and are analog-converted at a sampling frequency of 330fh. The second horizontal synchronizing signal RH of opposite polarity to the image signal from the synchronizing generation circuit 40 is respectively inserted in this analog-converted signal.

This forms an added arc of the second horizontal synchronizing signal RH and the burst signal RB as shown in the waveform D diagram in each channel. In addition, the burst signal RB is inserted before the DA conversion so that the phase information is correct, and the horizontal synchronization signal RH is inserted after the DA conversion, so that the dynamic range of the DA conversion can be effectively used.

These signals are supplied to the rotating head 43 provided with two and four heads through the recording circuits 41a and 41b and the recording and reproducing switching switches 42a and 42b, and the above-mentioned on the tape 44 Each channel is made up of one track, and recording is performed so that a video signal of one field is formed from two tracks.

At the time of reproduction, the signal reproduced by the rotating head 43 on the tape 44 is drawn out through the switches 42a, 42b, the reproduction circuits 45a, 45b. These signals are equivalent to the signals in waveform D, respectively, and contain jitter components. These signals are supplied to AD conversion circuits 46a and 46b, respectively, and are digitalized at a sampling frequency of 330fh. In addition, signals from the reproduction circuits 45a and 45b are supplied to the PLL clock generation circuits 47a and 47b, respectively, to form clock signals of a predetermined frequency including jitter components. The signals from the AD conversion circuits 46a and 46b are again supplied to the time base correction circuit (TBC) 49 through the dropout compensation circuit 48 and the clocks from the generation circuits 47a and 47b. A signal is supplied to the TBC 49, and a signal from the timing control circuit 50 is again supplied to the TBC 49, so that time axis correction of the reproduction signal is performed.

A delay circuit 51 for correcting the delay in the delay circuit 37 at the time of recording is provided in the channel on the signal side reproduced by the head on the trailing side of the two heads in these time-base corrected signals. The signal is supplied to the channel synthesis and time base compression circuit 52, so that the signal is subjected to compression synthesis in reverse operation with the decompression circuit 34 at the time of writing.

The digital frame synchronizing signal from the generation circuit 35 is inserted into this signal, supplied to the DA conversion circuit 54, and analogized at a sampling frequency of 600 fH. As a result, a TCI signal from which the jitter component has been removed is formed, and the signal is output to the output terminal 55.

Therefore, in this apparatus, the same operational effects as those in the first embodiment are obtained, and in this example, the frequency band is narrowed by the time-base extension at the time of recording, so that recording and playback can be performed using a narrow-band video tape recorder. have.

According to the present invention, since the second synchronization signal and the burst signal, which are easy to be separated at the time of recording, are added, and they are separated at the time of reproduction, time axis correction and the like are made, so that a good video signal can be easily reproduced.

Claims (1)

In recording and reproducing a video signal provided with a horizontal synchronizing signal having the same polarity as that of the image signal between horizontal periods of the image signal, recording is performed by adding a second horizontal synchronizing signal having a reverse polarity and a burst signal with the image signal at the time of recording. And extracting the second horizontal synchronization signal as level detection at the time of reproduction, extracting the burst signal as the extracted second horizontal synchronization signal, and using the extracted burst signal, the image signal and horizontal synchronization And reproducing the video signal by removing the time axis error of the signal.

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