DE3343138C2 - Multiplex recording system and possibly playback system for a video tape recorder - Google Patents

Abstract

A multiplex recording and reproducing system records and reproduces an audio signal on a track that has stored a video signal. A rotating part, around which a magnetic tape is guided, carries a plurality of video signal reading and recording rotary heads and a single audio signal reading and recording rotary head which is exclusively assigned to the audio signal and in front of one of the video signal reading and writing heads is arranged at a predetermined angular distance. The audio signal read and write head has an azimuth angle which is substantially larger than that of the video signal read and write heads.

Description

are two channels of a two-channel stereophonic audio signal.

5. Multiplex recording and playback system according to one of the preceding claims, characterized by a recording processing device, which comprises a first frequency-modulated audio signal from an audio signal which occurs at each interval of a track scanning period, and a second frequency-modulated audio signal delayed by one track scanning period from an audio signal, which occurs at every other interval of a track scan, records and generates a frequency division multiplexed signal from the first and the second frequency-modulated audio signal in the same track scan period and supplies the multiplex signal to the audio signal magnetic head (Ha) at an interval of each track scan period, and which the audio signal magnetic head (Ha) and the video signal magnetic heads (Hu H ₂ ) controls in such a way that the audio signal magnetic head (Ha) generates an audio track on the magnetic tape (14) which contains the first and second frequency-modulated audio signals at a distance of two tracks stores, while the video signal magnetic heads (Hu H ₂ ) generate video tracks which store video signals at a distance of one track, the video track formed by the other video signal magnetic head being superimposed on the previously recorded audio track, and a reproduction processing device which stores the first and the second frequency-modulated audio signal differs from the reproduced signal, which is read by the audio signal magnetic head (Ha) , which scans the track comprising the audio track and the video track superimposed thereon, whereby two demodulated audio signals from the first and second frequency-modulated audio signals in chronological order are composable.

The invention relates to a multiplex recording system and possibly a playback system for a video tape recorder according to the preamble of claim 1.

The prior art is a magnetic recording and reproducing device (video tape recorder) known with oblique scanning that a variety of rotary heads, such. B. has two that at a drum or a similar rotating part are arranged at the same angular distance. A magnetic tape is guided around the rotating part over an angular range which, for example, is slightly larger than Can be 180 °. The rotary heads on the rotatable part are adapted to send video signals onto the magnetic tape to write. A stationary head is arranged on the moving path of the magnetic tape so that he writes on this audio signal. During playback, the rotary heads read the video signals and the stationary one Head reads the audio signals.

A common trend in the field of videotape recording is to use a longer recording time. and playback time, and consequently a lower running speed of the magnetic tape to achieve. At the same time, there is an increasing demand for better quality audio signals when playing Because the relative speed between the running tape and the stationary head for writing and reading audio signals is low there arises a difficult situation that a decrease in the running speed of the tape greatly affects the frequency characteristics of audio signals compared to those of video signals, which are written and read with the rotary heads, which prevents au-

3 4

Write heads H \ and H ₂ reproduced audio signals with the desired quality . These heads H \ and H ₂ are standing

will. each other at an angular distance of 180 ° over the

From the starting point of the invention according to the circumference of the rotary drum 10 opposite. The rotary preamble of claim 1 forming DE-OS drum 10 also carries an audio signal reading and 32 09 112 a system has become known in which a 5 write head H _{A is} superimposed on a video signal at an angle θ with respect to an audio signal, according to intended direction of rotation of the rotary drum 10 before converting it into a predetermined mode to the video signal reading and recording head Hi. Alworden and in which the superimposed signals on an Ie heads H \, H2 and Ha are non-rotatably connected to the rotary current magnetic tape by means of a rotating video signal recorder 10 and are for this reason recorded in the gnet head on the magnetic tape and from to the following as As shown in FIG. 2 read this. In such a system, as is shown, the heads H _x and H _{2 are positioned} on the same rotary head, the audio signal is positioned on the magnetic tape height on the rotary drum 10 and writes with and reads from this and therefore has a high clearance d above the Head Ha- The Drehtromtivgeschwindigkeir between tape and head prevails mel 10 is above a stationary drum 12 so the recording and playback quality is arranged that a smaller distance between their water than in the system in which an audio signal by means of the bottom and the top the drum 12 is present
of a stationary head is recorded and read. A magnetic tape 10 is guided by guide posts 16a. and 166 so guided that it extends over an angle of

In the case of the above-described recording, a little more than 180 ° around the rotary drum 10

n and playback system, the audio signal 20 is extended, wherein it is relative to the rotary drum 10

is subject to at least one frequency modulation and tends to be during a recording or playback

then superimposed on a video signal which is from a dispensing operation, the rotary drum 10 about its axis

frequency-modulated brightness signal and a color in the illustration in FIG. 1 counterclockwise and

carrier signal in the lower range (low range) formed the magnetic tape 14 in a direction indicated by an arrow X

can be, with the superimposed signals driven with an indicated direction.

The rotary heads H \ and H ₂ differ in their

the. This leads to the difficulty that beats are azimuth angles from each other. The rotary head Ha has a

occur between the carrier frequencies and at an azimuth angle which is significantly greater than

In a reproduced image, interference (moire) comes from that of the rotary heads H \ and H ₂ as it is still

be called out. 30, one of the rotary head H ₂

It is therefore an object of the invention to create a video track formed and an audio track formed by the rotary head H _A multiplex recording and possibly reproducing system during a recording process for a video tape recorder which the previous one at the same position on the magnetic tape 14 solving the difficulty mentioned above and arranging a moiré-free. Therefore, it is preferred that the sub can provide picture with high sound quality. 35 differed with regard to the azimuth angle between the

This object is achieved by the characterizing heads H ₂ and Ha greater than that between the features of claim 1, embodiments of the rotary heads Wi and H _A. The azimuth angle of the rotary invention are the subject of the dependent claims, head Ha must be different from those of the rotary heads H \ and H ₂

The invention will be different in the following on the basis of execution, so that the audio signal without inter-

examples can be reproduced with reference to the drawings 40 reference with the video signal

explained in more detail. It can show. It should preferably be sufficiently larger than

F i g. 1 and 2 are top and side views, respectively, showing one of the rotary heads H 1 and H ₂ to allow for a minimum of head assembly and the like in accordance with the invention, which may occur during weighing; in this particular execution

F i g. 3 is a block diagram of a recording system where the azimuth selected for rotary head H \

stems, which has the invention, mutwinkel -6 ° C, that for the rotary head H ₂ + 6 °

F i g. 4 is a graph showing an example and that for the rotary head Ha -30 °.

te frequency signal spectra that are generated by the system so that the video track which the rotary head H ₂ forms

recorded and reproduced according to the invention and the audio track which the rotary head Ha generates

50 can be placed in the same place as it

F i g. Fig. 5 is an illustration of an exemplary band assembly described above is the rotary head Ha

sters, which by the system according to the invention in front of the rotary head H \ by the angle θ and below

can be recorded and reproduced, the rotary head H \ arranged with the distance d . at

F i g. 6 is a block diagram of an essential part of the illustrated embodiment, the rotary current

Another embodiment of the recording drum 10 has a diameter of 62 mm, the angle θ

stems, is 55 ° and the distance d 13 μm. Because of the verti-

F i g. 7 is a block diagram of an example of a portion of the cal distance d the rotary head Ha begins with

the in F i g. 6 training shown, generation of an audio track at a point, which around

F i g. 8 is a block diagram of a playback system about 18 μπι deviates from the point where the rotary

according to the invention, and 60 head H ₂ begins to form a video track. Each-

Fig. 9 is a block diagram of another embodiment, but this deviation is of microscopic size

form of the playback system. and in the practical case negligible.

It is shown on the fig. 1 and 2, reference is made to FIGS. 3 referred to, which is a Si

which represents an arrangement of different heads and similar signal processing system, which with the in

According to a preferred embodiment of FIG. 65, FIGS. 1 and 2 is connected.

Invention are shown. A rotary drum 10, for example, an input terminal 18 receives the Au-

That is an exemplary rotating part has an input terminal 20 on its audio signal of a left channel

fixed a pair of video signal read and the audio signal of a right channel and an input

5 6

output terminal 22 a common color signal. signal recording system 44 generates a carrier color. The audio signal for the left channel is derived from the signal in the lower range, which is a frequency / .um input terminal 18 of a 1-field delay switch conversion into a lower band range than the FM! device 24 is supplied to have passed through this by a period of brightness signal and to be delayed in a manner which has been phase-shifted equal to a field period 5 in order to prevent an over (frame period) of a conventional speech to be recorded. The FM luminance signal and color video signal is. The output of the 1-Teilbildverzö- the carrier color signal in the lower area, whose color generation circuit 24 is connected to a frequency modulator auxiliary carrier frequency 629 kHz, is applied to a 24. At the same time, the audio signal for the mixer circuit 46 for performing a frequency _t left channel is fed directly to a frequency modulator 28 10 division multiplexing process. The output is fed without any delay. The signal of the mixer circuit 46 is fed via rotary transformers of the right channel, on the other hand, from the input terminals 48 and 50 to the rotary heads Wi "terminal 20 connected to them, to a frequency modulator 32 via a and W2 |" 1 -field delay circuit 30 and directly a- The various signals which, according to the invention, are fed to the frequency modulator 34, recorded 15 the magnetic tape 14 or read from it, have frequency spectra as shown in FIG common embodiment are shown and comprehensive F i g. 4. In F i g. 4 represents FM Y the Fresen individual charge transfer devices such quenzspektrum of the FM luminance signal output from z. B. bucket brigade devices or charge-coupled to the luminance signal recording system 42 and C The frequency modulator 26 carries the frequency spectrum of the carrier color output signal ner carrier frequency / 1 (e.g. 1.1 MHz) with the delayed audio signal of the left channel recorded in the lower range of the carrier color signal Au A2, Aj wind Aa iation through, whereby a first / -M audio signal is the Freq uence spectra of the first, second, third, respectively, is generated. The frequency modulator 28 is frequency-modulated FM audio signal. As shown in FIG. 4 shows a carrier frequency U (e.g. 1.85 MHz) with the 25 are the first to fourth FM audio signals on a non-delayed audio signal of the left channel and the lower frequency limit of the band generates a second band FM audio signal In the same FM brightness signal is adjacent, and these signals generated the frequency modulator 32 a third FM are recorded on the magnetic tape with the saturation level audio signal by a carrier frequency / 2 (1.35 MHz)

with the delayed audio signal of the right channel 30 In the following, a band pattern is modulated in superimetric frequency, and the frequency modulator 34 is described with the invention. Assume that a fourth FM audio signal is generated by a carrier that the rotary head H _A has started to transmit the frequency / 3 (e.g. 1.6 MHz) with the non-delayed frequency division multiplex signal of the first to fourth FM audio signal. Audio signal of the right channel frequency-modulated audio signal to be recorded on the magnetic tape 14. Then it will be. The first to fourth FM audio signals have a longitudinal direction of the magnetic tape inclined position to bilateral, maximum frequency deviation such as e.g. B. the. At one by a time interval which is the angle ± 100 kHi and a mixing circuit 36 moves the rotary drum 10 by the angle θ in order to generate a frequency multiplex signal. The multiplex output of the mixer circuit 36 will form a video track which is fed under the same gate 38 which is inclined repeatedly at every angle as the audio track and opens and closes at one point field period so that the mixing starts upstream of the audio track with respect to the magnetic circuit output at every interval of a sub-picture tape. The video track stores the frequency diode is given. The output of the gate 38 is muitipiexsignai which is supplied gnal- formed of the FM luminance signal through a rotary transformer 40 to the single Audiosi- 45 and a carrier color signal in the lower region read and -Schreibdrehkopf H _A In this way, form the rotary heads H _A or . Wi the In the manner described, the audio signal in the audio track and video track at the same time with each of the two channels in the first and second (or third predetermined time gap. When the rotary head Wi and fourth) FM audio signals through frequency module the guide post 16ö , which is shown in FIG. 1 shows nation of different carrier frequencies / i and / ₄ (or 50 hert completes the recording of data in / 2 and / 3) in a first audio signal which appears for each of an audio track (an audio track was at the predetermined interval of a field period and a second time before the audio track was completed). Dar audio signal, which at every other interval of a then the rotary head W2 begins to appear a video track on the field period converted to form the two FM bands 14.

Audio signals are subjected to a frequency-division multiplexing 55 The position where the rotary head W2 is to form a video track in the same one field period is downstream by one track pitch to the downstream, and that multipiexsignai is given every interval on the magnetic tape of the video track formed by the rotary head Wi fed to the rotary head H _{A for one field period} and transferred to the - meanwhile, the normal color video signal, since an audio track has already been formed, which occurs at the input terminal 22, the rotary head W2 therefore records a video track on the quality signal recording system 42 and a video track supplied to the Auger color signal recording system 44 previously formed on the magnetic tape. the underlying audio track is separated into a brightness signal and a carrier color signal through to fourth FM audio signals of lower frequencies. The brightness signal recorded as indicated by A \ to A ₄ in Fig. 4 indicated system 42 generates an FM brightness signal with 65. Due to the relatively long recording waves of a carrier frequency deviation, which, for example, the FM audio signals with the saturation level of 3.4 M Hz and gel deep into the magnetic layer have been written, a white The peak of 4.4 MHz gives the carrier color

7 8

Video track overlying the audio track, the FM-Hellig recording track Tc and an audio signal recording track signal shown only in a part of the magnetic layer near voltage track Ta . Reading and recording systems recorded on the surface of the magnetic tape 14, which are assigned to the tracks Tc and Ta , have been played in, since it has a high frequency, as is not denoted by direct FM-Y in FIG. 4 with regard to the meaning of the invention is. Therefore, the FM-5 role and therefore the description thereof is omitted audio signal is hardly read from the FM luminance signal. The track Ta stores audio information which erases. The carrier color signal in the lower region has a lower frequency directly on this with a stationary head without, on the other hand, a lower frequency, as has been recorded with C in frequency modulation. Therefore, Fig.4 is designated, which is a deep area that is recorded when the magnetic tape 14 is reached by a conventional magnetic layer when it is reproduced on the magnetic tape 14 to chen video tape player, the tendency is that the audio signal removed from track Ta,
Erase the previously recorded FM audio signal. It is shown on the fig. 6 and 7 reference is made to the invention, however, while the FM audio shows a second embodiment of a recording system signal, as already mentioned with the saturation level stems according to the invention. In FIG. 6, the same is recorded, the superimposed carrier color frame or similar components as those in FIG. 3 with gnal in the lower area with a lower level than the same reference numerals. The video saturation level recorded. This keeps the FM signal recording system in this embodiment audio signal at the reproducible level, agrees with that of Fig. 3 and is therefore omitted for the sake of simplicity, whereby the FM audio signal by the carrier color is omitted.
gnal is deleted to a negligible extent. 20 According to the illustration, the second FM audio signal is therefore even if the video track of the audio track signal output from the frequency modulator 28 is superimposed by the rotary head H ₂ , the FM delay and frequency conversion device 52 audio signal remains in the magnetic layer with the reproduced and a mixer circuit 54 is supplied. The fourth FM-baren level is present while the carrier color signal audio signal output from the frequency converter 34 in the lower range and the FM brightness signal at the 25 is a delay and frequency conversion point on the magnetic tape 14 recorded device 56 and fed to the mixer 54,
will. The delay and frequency conversion in-Immediately before the rotary head H ₂ begins a video track directions 52 and 56 are terminated in the same way as those on the magnetic tape 14, the rotary head is formed as shown by way of example in FIG. According to Ha to generate another audio track at a point, 30 Fig. 7, the second or fourth FM audio signal, which is two lateral track spacings from the one immediately arriving at a terminal 58, is converted into a digital preceding audio track. Written on this white memory 60. An oscillator 62 generates audio tracks containing FM audio signals of square waves, the frequency of which is recorded, for example, by the rotary head Ha , at 2.95 MHz, and supplies them to a counter 64. The lateral distance of two tracks on the magnet 35 Counter 64 is designed so that it is generated by a tromband 14, and video tracks which are reset with the carrier pulse generated by known color signals in the lower range and the FM brightness average with a period which is the same of the signals from the rotary heads H 1 and H ₂ recorded period of one rotation of the rotary drum 10 and with which are synchronized with a lateral distance of one rotational phase, the drum pulse generating track. The rotary head H _{2 is} superimposed on a video 40 which is sent to the input terminal 66. The counter 64 tracks the previously recorded audio track. counts the right-hand signals supplied to it by the oscillator 62. In this track generation process, the four corner waves and outputs a counter output to the digital FM audio signals on a track scanning period of the rotary memory 60 as an address signal.
head Ha divided as recorded audio signals In the above arrangement liewobci approximately one track scanning period of the four FM 45 fert the digital memory 60 to the following Bandpassfil audio signals is omitted while the rotary head Ha ter 68 a digital FM audio signal, which around one of the magnetic tape 14 not affected This means that the time period has been delayed during which the recording of the FM audio signals on the Ma track with video information has been finished. that is, the band-pass filter 68 generates a sinusoidal wave. It is shown in FIG. 5, which shows both the same band as the FM audio signal, a playful band pattern that was applied to the input terminal 58 with the system. Which can be achieved according to the invention. The magnetic output of the bandpass filter 68 is a frequency band 14 carries various tracks which are individually fed relative to the converter 70, which also runs a sinusoidal longitudinal direction of the magnetic tape 14 at an angle. 55 wave of, for example, 2.95 MHz from an oscillator. In the case of the various tracks, the white sol- tor 72 is being fed. The frequency converter 70 performs a frequency conversion on the incoming FM before video tracks generated by the rotary head H \ , and hatched tracks represent the overload audio signal frequency and the sinusoidal frequency of the video track generated by the rotary head H _2. The output of the frequency converter 70 is represented on the audio tracks. It is assumed that 60 each track, whether it is an audio track or a Vi, which is such a frequency characteristic deo track, is output to an output terminal 76 via a band-pass filter 74 has a width TW and a lateral one that it has a difference component between the track pitch TP to the neighboring one, since neither filters the two frequencies

Safety strip appears between successive tracks. Therefore, when the second FM audio signal is formed in this example, the track 65 with a frequency of 1.85 ± 100 kHz to the single width 7TV is identical to the track spacing TP. Each track input terminal 58 is applied, the first FM audio signal has a storage capacity to store a field video whose frequency is 1.1 MHz ± 100 kHz on the signal. In Fig. 5 is also a control signal output terminal 76. When the fourth FM audio signal

9 10

at the frequency of 1.6 MHz ± 100 kHz to the FM demodulators 88, 90, 92 connected to them

input terminal 58 is applied, the third FM audio and 94 occurs.

signal with a frequency of 1.35 MHz ± 100 kHz. The FM demodulator 88 performs a frequency demo

of output terminal 76. The first and third FM modulation on the first FM audio signal through and

Audio signal output from the delay and fre- 5 fert the audio signal delayed by one frame for the

Quenzumwandlereinrichtungen 52 and 56 are with left channel and outputs this signal to a terminal a

the second and fourth FM audio signals through that of a switch 96. The FM demodulator 82 generates the

Mixing device 54 is frequency-multiplexed. The audio signal for the right one was delayed by one frame

The output of the mixing device 54 is via the rotary transport channel. At the same time, the FM demodulator 90 generates

formator 40 supplied to the rotary head Ha. As with the io, the audio signal for the left channel and carries it

The first embodiment supplies an unillustrated one field delayed delay circuit

Tor the rotary head Ha gradually or gradually 100 to which a charge transfer device or

at each interval of a field with the first to the like. The FM demodulator 94 outputs the audio

fourth FM audio signals. audio signal for the right channel again, which then

In Fig. 7, the delay and frequency 15 of a delay circuit delaying a field

Conversion devices 52 and 56 the oscillators 102 is fed. The outputs of a partial picture

62 and 72 and the counter 64 (provided that hesitant delay circuits 100 and 102 are

f \ + U = h + Λ) with each other. While the Os- den is given to the terminals b of the switch% or 98,

zillatoren 62 and 72 independently of each other originally Each of the switches and 98% and a switch 104,

which, they may comprise a single oscillator, 20 is described, is designed to be alternating

since their oscillation frequencies are the same. If the terminals a and b at each track scanning

desired, the delay and frequency period (one field period in this embodiment)

Conversion devices 52 and 56 of the up and depending on the to an input terminal

Drawing system and the playback system 106 combined drum impulses forms. During one

sam can be used as in the recording 25 field period during which the rotary head Ha a

system according to FIG. 9 is shown. According to this specially superimposed recording track is scanned, the switching

the embodiment of which provides the resetting of the ter connected to the terminals a, as shown in FIG. 8

Counter 64 by the drum pulses shows a substantial. In the case of the in FIG. 8 provides the position shown

the exact delay time of a partial image. Switch 98 the output signal of the FM demodulator

It is shown on the fig. Referring to Fig. 8, there is shown a 3088 connected to an output terminal 108, ie, the two types of display system according to the invention. In of audio signals for the left channel, which are shown in the above-F i g. 8 are the same or similar components as stored track in memory, one of the other being those in FIG. 3 with the same reference numerals if preceded by a field period is drawn in the same way. The rotary head Ha in FIG. 8 probes the in F i g. 5, hatched tracks are obtained at the output terminal 110 of the switch, in which audio tracks and 35 98 one of the two types of audio signals for the right video tracks are one above the other (for the sake of simplicity, the channel that is one field period in front of the other is shown below the designation is concerned

superimposed recording tracks are used). As While the rotary head Ha forth a superimposed Aufhergehend specified, each audio track by the recording track scanning of the rotary head H \ scans a rotary head Ha, the azimuth angle, for example 40 video track is displayed in white in Figure 5, is -30 °, and each of the audio track superimposed Vi from a predetermined delay time. The formed of deospur by the rotary head Hi whose Azi- the rotating head H \ from the video track scanned Vimutwinkel example, + 6 ° is Therefore, the is deosignal a luminance signal reading system of erwähn- 114 rotary head Ha previously during scanning and a carrier color signal-reading system 1 16 over the th, superimposed recording track due to the azimuth 45 rotary transformer 48, a preamplifier 112 and the mut-loss effect only the first to fourth FM-Au switch 104 is supplied, which is reproduced in contact with a audio signal. Terminal a is up The brightness signal reading system

The video signal lying on both sides of a superimposed recorder 114 filters the reproduced FM luminance trace on the magnetic tape 14, demodulates it to a reproduced brightness , which has been generated by the rotary head H \ , the speed signal in the original tape and then carries it for example, has an azimuth angle of −6 ° to a mixer circuit 118 . The carrier color signal line in relation to the audio track is therefore a security system 116 filters the reproduced carrier color strip, which corresponds to the width TTV of the essentially individual signals in the lower area, formed around the original tape of the video track which the rotary head is restored and removed using Ha egg it prevents previously recorded FM 55 nes comb filter, the carrier chrominance signal in the lower loading audio signals in adjacent superimposed Aufzeich- rich reproduced from crosstalk from adjacent superimposed voltage traces as a generic speaking, currency th recording tracks. In this way, the rend takes a specific superimposed recording track, carrier color signal reading system 116, only the carrier color is scanned. gnal on which of the scanned track was read

The thus from a superimposed recording track 60 has been and feeds it to the mixing circuit 118 . The reproduced mixing circuit 118 that is scanned by the rotary head Ha mixes the two input signals, first to fourth FM audio signals, and leads them as a reproduced, normal video- speaking bandpass filter 80, 82, 84 and 86 via the color signal to an output terminal 120. as long as the rotary transformer 40 and a preamplifier 78 to-rotary heads H _a and Hi completely scan the tracks out, since the center frequencies of the bandpass filters 80, 65, the switches 96,98 and 104 individually to the other 82, 84 and 86 is predetermined so are that they Λ, £, / 2 or h clamps b placed while the rotary head // 2 are so, they pick up the first to fourth FM audio starts, an overlaid recording track abzutagnale by frequency selection and perform this the most. Due to the aforementioned azimuth

11 12

Loss effect gives the rotary head H ₂ only the signal besystem according to FIG. 9 is identical to that of the

again, which is in the video track in the overlaid Fi g. 8 and has therefore been omitted. That

Recording track has been recorded without the second reproduced FM audio signal from the

Play the FM audio signal in the audio track. The bandpass filter 82 is a delay and frequency

That is to say, the rotary head H ₂ is fed from the superimposed input converter 124. The four

drawing track again the frequency-multiplexed signal, te reproduced FM audio signal output from the

which consists of a carrier color signal in the lower range of bandpass filter 86 is a delay and frequency

and an FM brightness signal. The weighing converter 126 is supplied. The Ver-

the given multiplex signal is used for brightness delay and frequency conversion devices

Playback system 114 and a carrier color signal 10 124 and 126 are designed in such a way that they are around a

Playback system 116 via a preamplifier 122 partial picture delayed FM audio signals with carrier frequency

and the switch 104 is supplied, which at this time generates time sequences of f \ and f ₂ by a delay

point at the terminal b . Since the display system is about a field and a frequency conversion

me 114 and 116 is performed in the manner previously discussed. The delay and frequency

work, the mixing circuit 118 outputs to an output 15 conversion devices 124 and 126 work des-

input terminal 120 a read video field signal of the half in the same way as the delay and

superimposed recording track as reproduced, frequency conversion devices 52 and 56 in the up-

normal video color signal. As before, designation system and can be formed from the latter

wrote, draw the different azimuth angles to be.

having rotary heads H ₂ and Ha different 20 The switch 96 receives the reproduced, first re-

Types of information on top of each other and read the given FM audio signal with the carrier frequency

successively with the special azimuth angles f \ from the output of the bandpass filter 80 and the again-

the end. This hardly leads to a mutual interference given, second FM audio signal, which is a partial

is delayed between an FM audio signal and a carrier color image and has the carrier frequency f \,

signal in the lower range and an FM brightness signal from the output of the delay and frequency

gnal, which would occur due to a beating- Conversion device 124. The switch% switches the

de, if a single rotary head is used, these two inputs at each interval of a field period

record and read at the same time. As a result, to combine them one after the other, whereby

This results in a reproduction of the video color the switch output is sent to the FM demodulator 128

signal and the audio signal of high quality. 30 leads. The switch 98, on the other hand, receives the

Meanwhile, while the rotary head H _{2 is} an overloaded third FM audio signal, which the carrier

gerte recording track is scanned by the two gerfrequency f ₂ has from the output of the bandpass filter

Kinds of reproduced FM audio signals for each cat 84 and the reproduced fourth FM audio signal

nal, which from the rotary head Ha a partial image before the with the carrier frequency f ₂ . By switching at each

Scanning the same superimposed recording track 35 interval of a field period combined the switch

have been read, the audio signal of the left channel 98 these signals one after the other and the output

after the one field period of which one field has passed, the FM demodulator 130 is supplied. the

hesitant delay circuit 100 and the audio FM demodulators 128 and 130, respectively, provide the reproduced

signal for the right channel after the one sub-picture specified audio signals for the left and right

period of the delay channel delaying a field without interruption in the correct order.

Shahkreis 102 delivered. These audio signals are ge.

the other terminals 108 and 110 via the switch 96. 9 shown embodiment is inso- or 98 supplied. As a result of this, they appear to be as advantageous as a single FM demo module loading Audio signals for the right and the tion system are sufficient and the use of a game link Channel at output terminals 108 and 110 45 chers to the delay from one field out without interruption and in the correct calling, simplified the circuit structure compared Order on. with one where an analog delay element

Is used in the previously described embodiment.

form switch both switches 96 and 98 demodulated, the illustrated and described first and second

reproduced audio signals, so that compared to 50 th embodiments are only used for explanatory purposes.

the switching of FM audio signals, which by itself. With regard to the first and second FM audio

has a high frequency, circuit sub-signals are four different audio signals into

Background noise can be reduced if recorded overall in the embodiments and

Fluctuations in the drum pulses occur. read because the output signals for the right and the

According to the preceding description, 55 left channel can be modulated individually. on the other hand that the reproduced audio signal by a field can also sum and difference signals of the two period can be modulated relative to the normal Vi audio signal channels being played back. While such deofarbsignal is delayed However, a field-modulated signal takes a matrix circuit in the up period about '/ «> or V50 seconds, depending on the drawing and rendering system, so it may take Mains frequency derived standard, and is therefore in practice even a relatively inexpensive monophonic playback Case negligible. device can play a medium on which information

It is shown on the fig. 9, in which one recorded with the system according to the invention

second embodiment of a playback system. Furthermore, the audio signals are not on two

according to the invention is shown in FIG. 9, the channels of stereophonic audio signals are limited

Components that are common to those shown in FIG. 8 and 65 can be used with monophonic audio signals

indicated are present with the same reference numerals.

The audio signals can be digitally recorded on a magnetic tape

refrain from simplicity. A video signal can be recorded or read from playback. The A

Field delaying delay circuits 24, 30, 100 and 102 may include memories. Furthermore, the track width provided for the rotary head //. <Can be wider from that for the rotary heads H 1 and H ₂ , since in this case a safety strip is also defined between adjacent audio tracks, although this is narrower than the width of the video tracks

It is assumed that the audio signal of the left channel L, the audio signal of the right channel R, and signals produced by removing the signals L and R by one track scanning period (one field period during which a data field is written in one track will be) DL or DR . While in the embodiments the modulated signals of the FM audio signal having the carrier frequencies I _x , / 2, β and A were DL, D ¹ R, R and L , this was only for the purpose of explanation and can be represented by a combination of L, R, DR and DL are replaced by the one from R, L, DL and DR or that from DR, DL, L and R. Furthermore, none of the relationships described between the modulated signals and carrier frequencies is limiting if there is no need for the condition Λ + / 4 = h + / 3 to be met

According to the invention, even audio signals which overlap one another (by more than one field) can be recorded are drawn by taking them through a time compression for a short period of time (about 90%) Use of single chain devices or similar recorded and expanded upon playback. This would decrease the accuracy increase of switching base.

In addition, the build-up and fall of an audio signal, which can occur during the switching process in the overlap period, with relatively slow increases be provided to thereby result in a fade-in and fade-out, whereby in a high frequency range Switching noise can be kept low.

In summary, it can be seen that the invention provides a multiplex recording system and a multiplex recording and playback system for videotape recording and playback provides which are various Have advantages over previous systems. Since the FM audio signals on a tape with a rotary head assigned exclusively to this is recorded, the mutual disturbance between FM audio signals and video signals due to of beats between the carrier frequencies is greatly reduced compared to that Prior art system utilizing a single head for recording and reading multiplexed FM audio signals and video signals is used. The audio tracks produced by the special rotary head are each positioned in the same position as every second video track. This is compared in abbreviated form with the recording of video and audio tracks without overlapping, the recording and playback times not, and there is a security strip essentially through a video track between successive ones Audio tracking is set, this hardly leads to eo to a crosstalk. The use of a single rotary head to record audio signals reduces the required number of heads and rotary transformers each by one compared to the case where two exclusive rotary heads are used, thereby simplifying the construction will. The audio tracks can be provided with a larger width than the video tracks and this results a better signal-to-background ratio in the reproduced audio signals than in the case in which the Audio and video tracks have common dimensions. Furthermore, the background of the switching noise reduced, as the reproduced FM audio signals are frequency demodulated and then successively in time can be combined by switches which are operated individually at each interval of track scanning will.

In addition 8 sheets of drawings

Claims (4)

Patent claims: 1. Multiplex recording system and possibly playback system for a video tape recorder, comprising a rotating drum around which a movable magnetic tape is looped as a recording medium over a predetermined angular range, at least two video signal magnetic heads attached to the drum at a certain distance from one another These rotary heads have different azimuth angles from one another and record a video signal in inclined tracks on the magnetic tape, and an audio signal processing device in which a first frequency-modulated signal is generated from an input audio signal and, in parallel, a second frequency-modulated signal is generated by delaying the input audio signal by one track scanning period which are mixed with one another before the helical track recording, characterized in that a single audio signal magnetic head (H _A ) at a point in front of one of the two video signal magnetic heads on the drum (10) fe (H \, H ₂ ) is fixed at a predetermined angle (Θ) with respect to an intended direction of rotation of the drum (10) to which the audio multiplex signal is fed, the audio signal magnetic head (Ha) having one of the azimuth angles of the video signal Magnetic heads (H \, H ₂ ) has different azimuth angles. 2. Multiplex system according to claim 1, characterized in that the azimuth angle of the audio signal magnetic head (Ha) is substantially greater than the azimuth angle of the video signal magnetic heads (Hu H ₂ ) . 3. Multiplex system according to claim 1, characterized in that the video signal recorded by the video signal magnetic heads (H \, H2) is a frequency multiplex signal which is formed by a frequency-modulated brightness signal (FM-Y) and a carrier color signal (C) of lower frequency, which uses an empty band which is lower than a band of the frequency-modulated luminance signal (FM-Y) , and that the first and second frequency-modulated audio signals are recorded in a band which is adjacent to the lower limit frequency of the frequency-modulated luminance signal (FM-Y) . 4. Multiplex system according to claim 1, characterized in that the first frequency-modulated audio signal comprises two frequency-modulated audio signals (Au A4) which have a different band and are generated by modulating signals that are audio signals in two channels of a two-channel stereophonic audio signal, and that the second frequency-modulated audio signal comprises two frequency-modulated audio signals (A ₂ , A ₃ ) which have a different band and are modulated by modulation