KR910002759B1 - Video tape recorder - Google Patents

Abstract

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Description

Video tape recorder

1 is a block diagram of a digital audio recording video tape recorder according to an embodiment of the present invention.

2 is a conceptual diagram of a track on recorded magnetic tape.

3 is a spectrum diagram of signals recorded by the magnetic head group.

4 is a block diagram of a conventional 8 millimeter video tape.

5 is a spectral diagram of a signal recorded by a conventional 8 millimeter video tape recorder.

* Explanation of symbols for main parts of the drawings

51, 64: input terminal 35, 66: modulator

52, 54, 60, 67, 83, 85, 87, 89, 91: amplifier

58a, 58b, 63a, 63b, 70a, 70b: magnetic head

71: magnetic tape 59, 88: digital signal processor

84, 92: demodulator 86, 90, 94: output terminal

The present invention relates to a recording / playback apparatus capable of recording and reproducing video and audio signals, and more particularly, to a video tape recorder capable of recording and reproducing high-quality digital signals.

In recent years, recording and reproducing of audio have been performed using pulse code modulation (hereinafter referred to as PCM), and it has been possible to perform high quality. Also in a video tape recorder (hereinafter referred to as VTR), so-called hi-fi VTR converts audio signals into frequency-modulated (hereinafter referred to as FM) signals and records them on a tape, thereby improving sound quality. The so-called 8-million video was developed by applying such a technique, and it is possible to simultaneously record a voice using PCM and a voice using FM.

An example of the above-described conventional 8 millimeter video will be described below with reference to the drawings.

4 shows a block diagram of a conventional 8 mm video signal recording and reproducing section. 5 shows the spectrum of the recording signal on the magnetic tape. In FIG. 4, reference numeral 1 denotes a first input terminal into which a video signal is input, and numeral 2 converts a video signal applied to the input terminal 1 into a signal that can be recorded on the magnetic tape 12. In FIG. The first image processor (3) is the second input terminal to which the audio signal is input, (4) the first audio processor converts the audio signal applied to the input terminal (3) into an FM signal, ( 5) a first digital signal processor for converting a voice signal applied to the input terminal 3 into a digital signal, etc., 6 drives a control device 7 for controlling the running of the magnetic tape 12; The tracking processor (8) supplies a signal supplied from the first image processor (2) or the like to the magnetic heads (11a) and (11b) attached to the rotary cylinder (10) via the rotary transformer (9). In addition, the switching processor for amplifying the signal reproduced by the magnetic heads (11a) and (11b) and supplying it to the next stage, (12) is wound around the rotary cylinder (10) by the guide pin (13) to the arrow (A) Magnetic tape running toward the head, 14 is a second image processor for converting a signal supplied from the switching processor 8 into a video signal, 15 is a first output terminal for outputting a video signal, and 16 A second voice processor for demodulating the FM signal supplied from the switching processor 8 into a voice signal, 17 a digital output supplied from the switching processor 8, and a second output terminal 18 for outputting the audio signal. A second digital signal processor (19) for demodulating a signal modulated into a signal and converting the signal into an original audio signal is a third output terminal to which an audio signal obtained from the digital signal processor (18) is output.

The operation of the 8 millimeter video configured as described above will be described below. The image signal applied to the first input terminal 1 is converted into an FM signal which is converted into a luminance signal by the first image processor 2 and a color signal converted into a low range. Then, the FM signal output from the first image processor 2 and the color signal converted into the low range are applied to the switching processor 8. In addition, the two-channel audio signal applied to the second input terminal 3 is converted into a signal of one channel by the voice processor 4, then converted into an FM signal, and then applied to the switching processor 8. . The two-channel audio signal applied to the second input terminal 3 is also applied to the first digital signal processor 5 and converted into a digital signal of 10 bits of quantization and a sampling frequency of about 31.5 kHz. This digital signal is then 8-bit converted, added with a code for error correction, and then compressed in the time axis and further biphasic modulated. The bi-phase modulated signal thus obtained is applied to the switching processor 8. A tracking pilot signal generated by the tracking processor 6 is also applied to the switching processor 8 for tracking during reproduction. In this way, the signals applied to the switching processor 8 are added and amplified. The signal amplified and output by the switching processor 8 is applied to the magnetic heads 11a and 11b attached to the rotary cylinder 10 via the rotary transformer 9. Here, even when the magnetic head 11a or the magnetic head 11b is in the section indicated by the arrow B, the signal indicated in the recording signal spectrum of FIG. 5 is applied and is in the section indicated by the arrow C. The biphase modulated signal and the tracking pilot signal are applied. The symbol (a) in FIG. 5 is a tracking pilot signal, (b) a low frequency converted color signal, (c) an audio signal converted into an FM signal, and (d) a luminance signal converted into an FM signal. In this way, each signal is frequency-divided.

The magnetic tape 12 is wound around the rotary cylinder 10 with the guide pin 13 inclined with respect to the traveling direction of the magnetic tape. Since the magnetic tape 12 is traveling in the direction of the arrow A by the magnetic tape traveling device (not shown) controlled by the controller 7, the rotation of the rotary cylinder 10 is controlled. On the tape 12, each signal is recorded in an oblique track.

The following playback will be described.

The magnetic tape 12 is driven by the magnetic tape traveling device to reproduce a signal from the magnetic heads 11a and 11b. This reproduction signal is applied to the switching processor 8 via the rotation transformer 9 and amplified. The tracking pilot signal of the reproduction signal is applied to the tracking processor 6, and the magnetic heads 11a and 11b control the control device 7 so as to rotate along the track on which the signal on the magnetic tape 12 is recorded. Output a control signal. Tracking of reproduction is performed in this manner, so that signals are reproduced accurately.

Among the reproduction signals, the luminance signal converted into the FM signal and the color signal converted into the low range are applied to the second image processor 14, converted into an image signal, and then output to the first output terminal 15. The audio signal converted into the FM signal among the reproduction signals is applied to the second audio processor 16, is converted into the audio signal of one channel, and then output to the second output terminal 17. Since the time axis is compressed, the interphase modulated signal intermittently reproduced is applied to the second digital signal processor 18, and subjected to signal processing such as demodulation and error correction, and then digital-analog converted to perform two-channel audio. Is converted into a signal. Then, it is output to the third output terminal 19 of the two channels.

In this way, video and audio can be recorded and reproduced simultaneously.

However, in the above-described configuration, even if the audio signal using the PCM can be recorded, since the quantization is 10 bits and the sampling frequency is about 31.5 Hz, it cannot be said that the best sound quality can be obtained. In addition, only one channel is used for recording audio signals using FM, and recording of music and the like cannot be satisfied.

The present invention records a video signal and simultaneously records both a high quality audio signal such as a 16-bit quantized audio signal using a PCM with a sampling frequency of 48 kHz and a 2-channel audio signal using FM. Since a recording video tape recorder is provided, three groups of magnetic heads having different azimuth angles attached to the rotating cylinder, a modulator for converting an input signal into an FM signal, and a signal for converting the input signal into a digital signal are processed. Digital signal processor, a signal processor that separates an input video signal into a luminance signal and a color signal, a modulator that converts the luminance signal into an FM signal, and a low-frequency conversion of the color signal, and a carrier frequency of the luminance signal converted into an FM signal. With a switch for switching high, the input two-channel audio signal is converted into a two-signal FM signal and recorded on magnetic tape, Converts the voice signal of the input channel to the second digital signal is recorded on the magnetic tape. At the same time, the input video signal is converted into a luminance signal converted into an FM signal and a low frequency converted color signal and recorded on the magnetic tape. In this way, high-quality audio and video signals can be recorded at the same time. However, since the tracks on the magnetic tape on which each signal is recorded can be superimposed, the running speed of the magnetic tape can be increased, The narrow width eliminates the need for dividing into video and audio.

Hereinafter, a digital audio recording video tape recorder according to an embodiment of the present invention will be described with reference to the drawings.

Figure 1 shows a block diagram in one embodiment of the present invention.

In Fig. 1, reference numeral 51 denotes a first input terminal for inputting two-channel audio signals, reference numeral 52 denotes a first amplifier for amplifying input two-channel audio signals, and reference numeral 53 denotes a first input terminal. A first modulator 54 for outputting a frequency modulated two-channel modulated signal using the output signal of the amplifier 52 as a modulating wave, and 54 amplifies the output signal of the first modulator 53, thereby providing a first switch. A second amplifier (59) for supplying the first magnetic head groups (58a, 58b) attached to the rotary cylinder (57) through (55) and the first rotary transformer (56) is The first digital signal processor 60 for converting the output signal of the first amplifier 52 to analog-digital digital (hereinafter abbreviated as AD) and adding error correction code, interleaving, etc. The second magnetic head group 63a, amplified by the digital signal processor 59 and passed through the second switch 61 and the second rotation transformer 62 and attached to the rotation cylinder 57 ( Supplying to 63b) A third amplifier.

64, a second input terminal into which a video signal is input, 65, a first signal processor for separating the input video signal into a luminance signal and a color signal, and 66, a first signal processor 65 of the first signal processor 65. A second modulator 67 for outputting a frequency-modulated luminance signal and a low-frequency converted color signal as an input signal, 67 amplifies the output signal of the second modulator 66, so that a third switch 68 is used. And a fourth amplifier 71 for supplying to the third magnetic head groups 70a and 70b attached to the rotation cylinder 57 through the third rotation transformer 69, the magnetic tape, ( 80 and 81 are guide pins, and 82 are control devices for controlling the rotation of the rotary cylinder 57 and the traveling of the magnetic tape 71.

Reference numeral 83 denotes a fifth amplifier for reproducing the first magnetic head groups 58a and 58b so as to amplify a signal supplied via the first switch 55, and 84 denotes a fifth amplifier. A first demodulator 85 for demodulating the output signal of (83) and outputting two channels of audio signals is a sixth amplifier (86) for amplifying the demodulated audio signal in the first demodulator (84). The first output terminal, 87, to which two audio signals output from the sixth amplifier 85 are output, is reproduced by the second magnetic head groups 63a and 63b, and the second switch ( The seventh amplifier 88 which amplifies the signal supplied via 61) obtains a digital signal from the output signal of the seventh amplifier 87, performs deinterleaving, error correction, interpolation, and the like. A second digital signal processor for converting analog (abbreviated as DA) and outputting two channels of audio signals, 89 is an eighth amplifier for amplifying two channels of audio signals, and 90 is two channels of A ninth amplifier which is reproduced by the third magnetic head groups 70a and 70b of the second output terminal 91 for outputting the audio signal and amplifies the signal supplied via the third switch 68. (92) is a second demodulator for demodulating the output signal of the ninth amplifier (91), and outputs a luminance signal and a color signal. (93) converts the output signal of the second demodulator (92) to an image signal. A second signal processor 94 is a third output terminal to which a video signal is output.

Numeral 95 denotes a detector which detects a hole to be detected in the magnetic tape cassette and outputs a detection signal, and 96 denotes that the third amplifier 60 can be operated by an output signal of the detector 95. The first switch 97 is a second switch for switching the frequency of the carrier modulated by the luminance signal of the second modulator 66 higher by the output signal of the detector 95, ( 98) is a third switch for switching twice the traveling speed of the magnetic tape.

Reference numeral 99 denotes a fifth switch for operating the first switch 96 and for operating the fourth switch 100 for stopping the amplifying operation of the fourth amplifier 67. Denotes a tape traveling device for driving the magnetic tape 71.

The operation of the digital audio recording video tape recorder configured as described above will be described below with reference to FIG.

The main and negative two-channel audio signals input to the first input terminal 51 are amplified by the first amplifier 52 and applied to the first modulator 53. In the first modulator 53, as in the conventional so-called VHS pomat VTR, as shown in FIG. 3 (a), the primary channel audio signal is 1.3 MHz, and the sub channel audio signal 1.7 MHz. As a carrier wave, it is converted into an FM signal with a maximum frequency shift of ± 150 Hz. After the two carriers are mixed, they are amplified by the second amplifier 54 and attached to the rotation cylinder 57 via the first switch 55 and the first rotation transformer 56 switched to R. It is applied to the magnetic heads 58a and 58b constituting the first magnetic head group. In addition, the magnetic heads 58a and 58b constituting the first magnetic head group are attached in a 180 degree positional relationship to the rotation cylinder 57.

The output signal of the first amplifier 52 is also applied to the first digital signal processor 59 and is subjected to signal processing. Explain this. First, two main channel signals are AD-converted with 16 bits of quantization and 48 kHz of sampling frequency. Subsequently, addition of an error correction code or interleaving is performed to convert the signal into a signal synchronized with the rotation of the rotation cylinder 57, resulting in a digital signal having a transmission rate of about 2.6 Mbits / sec. This digital signal is applied to a modulator and converted into a four-phase phase modulated signal having a carrier frequency of 2.5 MHz.

Then, the band pass filter (band filter) outputs the frequency band limited to 2.5 MHz ± 1.3 MHz. The four-phase phase-modulated signal thus obtained is detected when the detector 95 detects a hole formed in the magnetic tape cassette and generates a detection output. Then, the first switch 96 is operated so that the third amplifier 60 is amplified. The magnetic head constituting the second magnetic head group attached to the rotation cylinder 57 via the second switch 61 and the second rotation transformer 62 switched to R after being amplified by the operation. It is applied to 63a, 63b.

In addition, the holes formed in the magnetic tape cassette indicate that the coercive force of the magnetic tape wound therein is large (for example, 400 elsets), and that the tape is digitally recordable. In addition, the magnetic heads 63a and 63b constituting the second magnetic head group are attached around the rotation cylinder 57 in a 180 degree positional relationship, and the first magnetic head group 58a and the magnetic The head group 63a, the magnetic head group 58b, and the magnetic head group 63b are attached very close to each other.

Next, the flow of the video signal will be described.

The image signal applied to the second input terminal 64 is separated into a luminance signal and a color signal in the first signal processor 65 and converted into a frequency signal and a low-frequency converted color signal in the second modulator 66. do. Here, if the detector 95 does not generate a detection output, as in the conventional so-called VHS pomate VTR, a low-conversion color signal with 629 kHz as a carrier wave and a sink peak at 3.4 MHz and white peak at 4.4 MHz When the detector 95 generates the detection output, the second switch 97 is operated so that the sink chip is 5.4 as shown in FIG. It is possible to obtain a luminance signal in which the back peak becomes an FM signal of 7 MHz at MHz. The luminance signal and the low-conversion color signal which became the FM signal thus obtained are mixed, amplified by the fourth amplifier 67, and then switched to R by the third switch 68 and the third rotation transformer 69. Via is applied to the third magnetic head groups 70a and 70b attached to the rotating cylinder 57. Further, the magnetic heads 70a and 70b constituting the third branch head group are attached in a 180 degree positional relationship around the rotation cylinder 57, and the magnetic heads 58a and (1) of the first magnetic head group ( The angle difference with 58b) is selected from 45 degrees to 60 degrees. In addition, when the detector 95 generates the detection output, the magnitude of the signal supplied to the third magnetic head groups 70a and 70b is increased by about 20% compared with when it is not generated.

In the rotary cylinder (57), the tape running device (101) controlled by the controller (82) by winding the magnetic tape (71) inclined with respect to the traveling direction of the magnetic tape (71) with guide pins (80) and (81). Is driven in the direction of the arrow E, and the rotation of the rotation cylinder 57 is also controlled and rotated in the direction of the arrow F. Therefore, the magnetic tape 71 is moved on the magnetic tape 71 with respect to the traveling direction of the magnetic tape 71. As an inclined track, the respective signals are recorded. The second magnetic head group is superimposed on the track recorded by the first magnetic head groups 58a and 58b so that the magnetic head group attached to the rotary cylinder 57 overlaps each of the recorded tracks. (63a) and (63b) record, and the height is determined so that the third magnetic head groups 70a and 70b can be written so as to overlap from thereafter. That is, the first and second magnetic head groups 58a, 58b, 63a, and 63b are attached to the same height, and the third magnetic head groups 70a and 70b are the same height. It is attached low to the magnetic head 58a. The conceptual diagram of the track recorded on the magnetic tape 71 recorded in this way is shown in FIG. 101a, 101b, 102a, 102b, 103a, and 103b shown in FIG. 2 are the first, second, and third magnetic head groups 58a, 58b, The tracks recorded by 63a, 63b, 70a, and 71b.

Although the tracks recorded on the magnetic tape 71 overlap each other, since the azimuth angles of the magnetic heads are different, signals having different azimuth angles are attenuated by azimuth loss at the time of reproduction. In order to maintain compatibility with the conventional VTR, the azimuth angles of the third magnetic head groups 70a and 70b are +6 degrees and -6 degrees, and the azimuth angles of the first magnetic head groups 58a and 58b. Chooses +30 degrees and -30 degrees. In this way, crosstalk between tracks is suppressed to prevent deterioration of the reproduction characteristics of video and audio. In FIG. 2, the inclined line in the track indicates the azimuth angle of the recorded signal.

In addition, the frequency of the carrier wave is selected so that portions having high signal energy do not overlap each other in the frequency band of the signal recorded by each magnetic head group. This shape is shown in the recording signal spectrum of FIG.

FIG. 3A shows the first magnetic head group 58a, 58b, FIG. 3B shows the second magnetic head group 63a, 63b, and FIG. 3C shows the third magnetic head group 70a, The recording signal spectrum of 70b is shown. As a result, the interference of each other can be reduced, and the attenuation degree of the previously recorded signal can be reduced even when the tracks to be recorded overlap. The second and third magnetic head groups 63a, 63b, 70a, and 70b are also recorded on the track recorded by the first magnetic head groups 58a and 58b. The signal levels that can be reproduced by the magnetic head groups 58a and 58b are attenuated by several 10 alpha B after recording by the second magnetic head groups 63a and 63b, but the third magnetic head group is reduced. Even if 70a and 70b are recorded thereafter, there is an effect that can be suppressed by an increase in attenuation of about 1? B.

The signal levels reproduced by the second magnetic head groups 63a and 63b are also attenuated by several 10? B by the third magnetic head groups 70a and 70b recording. However, since the four-phase phase-modulated signal is used in a narrower frequency band, the signal-to-noise ratio required to obtain the original audio signal from the audio signal converted into the digital signal can be secured, and the symbol error rate before correction is about 20 alpha B. ^Becomes 10 ^-4 or less.

On the other hand, the signal-to-noise ratio of the signal reproduced by the first magnetic head groups 58a and 58b can ensure a value equivalent to that of the conventional VTR, so that the reproducing sound performance of the so-called hi-fi VTR is obtained.

Next, the reproduction operation will be described.

The signal reproduced by the first magnetic head groups 58a and 58b is fed to the fifth amplifier 83 via the first rotation transformer 56 and the first switch 55 switched to p. Is applied to and amplified. The signal amplified by the fifth amplifier 83 is demodulated by the first demodulator 84 and converted into a two-channel audio signal. The two-channel audio signal thus obtained is amplified by the sixth amplifier 85 and output to the first output terminal 86. This audio signal is of high quality as can be said of the hi-fi VTR as described above.

On the other hand, the signal reproduced by the second magnetic head groups 63a and 63b is transferred to the seventh amplifier 87 via the second rotation transformer 62 and the second switch 61 switched to the P side. Is applied to. The signal amplified by the seventh amplifier 87 is converted into an audio signal by the second digital signal processor 88, but this is described next.

The four-phase phase modulated signal, which is an output signal of the seventh amplifier 87, is demodulated by a demodulator and converted into a digital signal. Thereafter, deinterleaving, error correction, and correction are performed. After correcting the time axis, DA conversion is performed to obtain an audio signal. The two-channel audio signal thus obtained is output from the second digital signal processor 88, amplified by the eighth amplifier 89, and then output to the second output terminal 90. Since the audio signal output to the second output terminal 90 is sampled at 48 kHz and quantized and recorded in 16 bits, it can be said that it is of the highest quality because it has a dynamic range of 90 dB or more and a distortion of 0.005% or less.

The signal reproduced by the third magnetic head groups 70a and 70b is applied to the ninth amplifier 91 via the third rotation transformer 69 and the third switch 68 switched to the P side. do. The signal amplified by the ninth amplifier 91, that is, the luminance signal converted into the FM signal and the color signal converted into the low range are applied to the second demodulator 92 and demodulated into the luminance signal and the color signal. At this time, when the detector 95 detects a hole formed in the magnetic tape cassette and generates a detection output, the second switch 97 operates to demodulate the luminance signal of the second demodulator 92. The frequency range drawn by the phase locked loop is switched to the higher one (if the frequency locked by the phase locked loop is wide, this is not necessary).

The luminance signal and the color signal obtained from the second demodulator 92 are converted into a video signal by the second signal processor 93 and output to the third output terminal 94.

Although the video signal recorded in this way can be reproduced, in the case of the magnetic tape 71 in which the detector 95 operates, the carrier frequency of the luminance signal is increased so that the frequency band of the luminance signal that can be recorded is wide and the resolution is high. High quality video signal can be obtained.

Next, the so-called apreco recording which records and corrects only the audio signal of the recorded magnetic tape 71 will be described.

When it is set to the mode which can make an apreco, the 3rd switch 98 is operated, the control apparatus 82 is switched, and the traveling speed of the magnetic tape 71 is doubled. By doing so, the tracks recorded by the first magnetic head groups 58a and 58b and the tracks recorded by the third magnetic head groups 70a and 70b do not overlap on the magnetic tape 71. Therefore, it is possible to erase and record each track independently.

By the way, since the first and second magnetic head groups 58a, 58b, 63a, and 63b have the same height and are extremely adjacent to each other, the tracks overlap in this case as well. Therefore, when the magnetic tape 71 recorded in the mode capable of apreco is rewound and the audio portion is recorded during reproduction, the first and second magnetic head groups 58a, 58b, ( The signals are recorded by the first and second magnetic head groups 58a, 58b, 63a, and 63b superimposed on the tracks recorded by 63a) and 63b. Then, the first magnetic head groups 58a and 58b record the tracks recorded by the second magnetic head groups 63a and 63b. In this case, the frequency of the signal recorded by the first magnetic head groups 58a and 58b is lower than the frequency of the signal recorded by the second magnetic head groups 63a and 63b. The signals recorded by the second magnetic head groups 63a and 63b are greatly attenuated.

In other words, the first magnetic head groups 58a and 58b operate as erase heads of the second magnetic head groups 63a and 63b. It is very effective because there is no need to install the magnetic head for erasing in particular. The frequency of the signal supplied to the first magnetic head groups 58a and 58b may be lowered and used only for erasing.

In this way, the recorded video signal remains as it is, and only audio can be recorded and corrected. The reproducing operation can be performed in the same manner as described above.

A case where digital audio is recorded on a conventional magnetic tape having no hole in the magnetic tape cassette and the detector 95 does not generate a detection output will be described next.

Since conventional magnetic tape has a small coercive force (for example, 600 el tes), a four-phase phase modulated signal for recording an audio signal converted into an FM signal, an audio signal converted into a digital signal, and a video signal can be recorded. It is not possible to record the three characters of the mixed wave of the luminance signal converted into the FM signal and the low frequency converted color signal as described above. If only the audio signal can be recorded. This can be seen from the fact that it is possible to record a mixed wave of the audio signal converted from the conventional VTR into the FM signal, the luminance signal converted into the FM signal for recording the video signal, and the low-pass color signal. Therefore, when only the audio signal is to be recorded on the conventional magnetic tape, the fifth switch 99 is switched and recorded. The output signal of the fifth switch 99 operates the first switch 96 so that the four-phase phase modulated signal output from the first digital signal processor 59 is transferred from the third amplifier 60. Switch to amplify. Thereafter, the same operation as described above is performed and the audio signal converted into the digital signal on the magnetic tape 71 is recorded as a four-phase phase modulation signal.

The output signal of the fifth switch 99 is also applied to the fourth switch 100, and the fourth switch 100 is operated to stop the amplification operation of the fourth amplifier 67. . For this reason, no signal is applied to the third magnetic head groups 70a and 70b.

Recording of the audio signal converted into the FM signal is performed in the same manner as described above.

In this way, although the audio signal can be recorded, the amplification degree of the third amplifier 60 is reduced, so that the four-phase phase modulated signal supplied to the second magnetic head groups 63a and 63b. The recording current value drops. In this way, since the coercive force of the magnetic tape 71 is small, the signal-to-noise ratio of both the audio signal converted into the FM signal to be reproduced and the four-phase phase modulated signal is improved. In this case as well, the first magnetic head group 58a, 58b can be used as the erasing head of the second magnetic head group 63a, 63b, similarly to the recording capable of the apreco.

In addition, although the case of the third magnetic head group has been described in the case of one pair of magnetic head groups 70a and 70b, the conventional magnetic head group is composed of two pairs of magnetic head groups which are placed adjacent to each other. You may also In this case, one pair is used similarly to the heads 70a and 70b of the third magnetic head group described above, and the other pair is used for long time recording. The recording tracks overlap with each other in the same manner as the conventional hi-fi VTR. However, three tracks overlap.

As described above, the present invention provides a modulator for converting an audio signal into an FM signal, a digital signal processor for converting an audio signal into a digital signal, and a converter for converting an image signal into an FM signal, and three groups having different azimuth angles. By installing the magnetic head, the video signal and the high quality audio signal can be simultaneously recorded and reproduced. In addition, by increasing the recording density of the recording track of the conventional VTR, it is possible to record the audio signal converted into a high quality digital signal. Thus, the function of the conventional Hi-Fi VTR is maintained as it is, and the high quality two-channel audio signal is added. Can be recorded. Moreover, since the magnetic tape recordable by the audio signal converted into the digital signal can be detected and recorded automatically, there is no mistake in handling and the operability is also good.

Claims (6)

A first magnetic head group comprising at least one pair of magnetic heads attached to a rotating cylinder, each having a different azimuth angle, and each magnetic head of the first magnetic head group attached to a position different from the first magnetic head group; A second magnetic head group composed of at least one pair of magnetic heads different from an azimuth angle and having a different azimuth angle, respectively, and attached to a position different from the first and second magnetic head groups; A third magnetic head group composed of at least one pair of magnetic heads different from the azimuth angles of the magnetic head groups and different from each other in the azimuth angle, and a first modulator for converting the first input signal into a frequency modulated signal; A first amplifier for supplying an output signal of the first modulator to the first magnetic head group, a first demodulator for demodulating a signal reproduced by the first magnetic head group, and the first demodulator. 1 input signal or second A first digital signal processor for converting an input signal into a digital signal and adding an error correction code; and a second amplifier for supplying the output signal of the first digital signal processor to the second magnetic head group. And a second digital signal processor for performing error correction and the like on the signal reproduced by the second magnetic head group and converting the signal into an analog signal, and a first signal processor for separating an input video signal into a luminance signal and a color signal. And a second modulator for converting the output signal of the second signal processor into a frequency-modulated luminance signal and a low-frequency converted color signal, and supplying the output signal of the second modulator to the third magnetic head group. And a third amplifier for converting the signal reproduced by the third magnetic head group into a luminance signal and a color signal, and converting the output signal of the second demodulator into a video signal. A second signal processor, a detector for detecting a detected portion formed in the magnetic tape cassette, and an output signal of the first digital signal processor to supply the second magnetic head group by the detection output of the detector. A first switch, a second switch for switching the carrier frequency of the luminance signal of the second modulator to a higher frequency by the detection output of the detector, a rotation of the rotary cylinder and a magnetic tape A video tape recorder characterized by having a control device for controlling driving. 2. The first track on the magnetic tape recorded by the first magnetic head group, the second track on the magnetic tape recorded by the second magnetic head group, and the third magnetic head group. Some, most or all of the third tracks on the recorded magnetic tape are superimposed, respectively, and after the first track is recorded, the second tracks are superimposed and the second tracks are recorded. And the attachment position and height of the first, second and third magnetic head groups to the rotation cylinder are set such that the third tracks are superimposed and recorded. 3. A signal according to claim 2, wherein a two-channel signal is used as a first input signal, the first modulator outputs two kinds of carriers corresponding to each input signal, and the first digital signal processor is a four-phase phase modulation. A video tape recorder, which is configured to output a signal. 4. The method of claim 3, wherein the frequency of the carrier wave output by the first modulator is selected to be higher than the frequency of the low-converted color signal, and the frequency of the modulated signal output by the first digital signal processor is determined by the first frequency. A video tape precoder characterized by a higher frequency being selected near the frequency of the carrier wave output by the modulator of 1. 5. A pair of first magnetic head groups attached to the rotary cylinders in a 180 degree positional relationship with each other, and a pair of second magnetic head groups attached to the rotary cylinders in a 180 degree positional relationship with each other. A video tape precoder having a third switch for attaching extremely close and switching the traveling speed of the magnetic tape in contact with the control device at high speed. 5. The fourth switch according to claim 4, wherein the fourth switch for supplying and stopping the output signal of the second modulator supplied to the third magnetic head group, the fifth switch for operating the first switch and the fourth switch. A video tape precoder characterized by having a switch.

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