FR2507047A1 - COLOR VIDEO SIGNAL RECORDING DEVICE OF THE SECAM SYSTEM AND RECORDING AND REPRODUCING DEVICE THEREOF - Google Patents

Abstract

In this system, a luminance signal of the colour video signal is separated by a first filter circuit and the carrier chrominance signal is separated by a second filter circuit, a third filter circuit (53) being provided which is supplied with the colour video signal in order to separate the luminance signal and to filter it with a delay time which is relatively shorter than the delay time of the first filter circuit, a pulse generator circuit (54, 63 (or 60-62), 57) for generating a pulse having a width which essentially corresponds to an interval between a time when an incoming horizontal synchronisation signal of the luminance signal arrives from the third filter stage, and an end position of the interval of the non-transmission of the carrier chrominance signal within the horizontal blanking period, of the luminance signal from the first filter circuit, and a first switch circuit (58) which is supplied with pulses from the pulse generator circuit in order to interrupt the transmission of the said low-band-converted carrier chrominance signal to the first mixing device which is provided for mixing the said frequency-modulated luminance signal and the low-band-converted carrier chrominance signal, during an interval which corresponds to the pulse width of the said pulse of the pulse generator stage.

Description

 The present invention relates generally to devices for recording color video signals from the SECAM system and to devices for recording and reproducing these signals. It relates more particularly to a device for recording and / or reproduction of color video signals of the SECAM system and to a device for recording and reproduction of these signals in which the signal to noise ratio (S / N) of the signal SECAM system color video, which is recorded and reproduced, is improved, and in which the synchronization of a central television receiver is stabilized, by interrupting a signal from a device for transmitting chrominance carrying signals with a pulse produced using a delay introduced by a filter, and this during a predetermined time interval within the erasure period.

Generally, in a system for recording and reproducing color video signals of the system
SECAM, when an undesirable noise component is introduced into a vertical erasure period and into a horizontal erasure period during which the signal of the chrominance subcarrier of the color video signal of the SECAM system does not exist, this unwanted noise component mixes with part of a luminance signal synchronization signal if this luminance signal and the chrominance carrying signal are mixed as is. In such a case, a circuit for separating the synchronization signal provided in the control television receiver operates erroneously. Consequently, the synchronism of the control television receiver becomes unstable, which introduces into the image. reproduced, vibrations, desynchronization and similar phenomena.

 Thus, as a device making it possible to eliminate the undesirable noise component in the vicinity of the horizontal synchronization signal in the period of horizontal erasure, the device described below is usually used in conjunction with the appended drawing. However, in the known device, there was a drawback in that the adjustment of the width of the pulses formed by the monostable multivibrators used in the device was excessively delicate, and that it was therefore difficult to carry out such an adjustment.

The object of the present invention is thus
- a device for recording color video signals from the SECAM system and a device for recording and reproducing these signals, which are new and particularly useful and in which the above drawbacks of the prior art have been eliminated;
a device for recording color video signals of the SECAM system in which the luminance signal is separated from the color video signal of the SECAM system by a second filter which has a delay time less than a first filter which separates the luminance signal in front between recording of the SECAM color video signal, the horizontal synchronization signal is separated and obtained from a luminance signal at the output of the second filter, the horizontal synchronization signal from the first or second filter is delayed by a delay circuit such that the trailing edge of the signal corresponds substantially to the position of the terminal portion of an interval of non-transmission of the chrominance-carrying signal within the horizontal blanking period, and the output signal of the device for transmitting the chrominance-carrying signal converted in the low band is interrupted for a predetermined time interval at the start the end of the horizontal erasure period using a pulse obtained by respectively mixing the input and output signals of the delay circuit in order to record; in the device according to the present invention, the position and the width (duration) of the noise triggering pulse within the horizontal blanking period are determined by the delay time of each filter; instability is thus eliminated, and it is no longer necessary to adjust the circuit to improve the signal to noise ratio;
- a device for recording and reproducing color video signals of the SECAM system in addition to the above recording device, in which analog processing of the signals is carried out in a reproducing device, as in the device above recording, so that reproduction is effected by interrupting, for a predetermined period of time within the horizontal erasure period, the output signal of the device for transmitting the reproduced chrominance carrying signal .

 In the device according to the present invention, it is unnecessary to make circuit adjustments, and the signal-to-noise ratio of the reproduced color video signal is improved. It is also possible to obtain an image reproduced in the television receiver with synchronization characteristics both horizontal and vertical which are stable.

 Various other characteristics of the inv-ntlon appear moreover from the detailed description which follows.

 Embodiments of the object of the invention are shown, by way of nonlimiting examples, in the accompanying drawing.

 Fig. 1 is a block diagram illustrating an example of a known device for recording and reproducing color video signals from a SECAM system.

 Fig. 2 is a graph illustrating the waveform of the color video signal from the SECAM system at the level of the horizontal erasing period and in its vicinity.

 Figs. 3 (A) to 3 (D) are graphs respectively showing waveforms of the SECAM color video signal at the level of the vertical erasing period and in the vicinity of this period.

 Figs. 4 (A) to 4 (F) are graphs respectively illustrating waveforms of signals at various parts of the device illustrated in FIG. 1.

 Fig. 3 is a block diagram illustrating an embodiment of a recording and reproducing device according to the invention of color video signals from the SECAM system.

 Figs. 6 (A) to 6 (G) are diagrams illustrating signal waveforms making it possible to explain the noise triggering operation in the vicinity of the vertical erasure period carried out by the device illustrated in the fig. 3.

 Figs. 7 (A) to 7 (G) are diagrams respectively showing waveforms of signals making it possible to explain the noise triggering operation in the vicinity of the horizontal blanking period carried out by the device illustrated in fig . 3.

 Fig. 8 is a block diagram illustrating a party. essential of another embodiment of the present invention.

 First of all, the known device is described, with reference to this effect in FIG. 1. During recording, a color video signal from the SECAM system is applied to a low pass filter 12 and to a band pass filter 13, via an input terminal 11. The pass filter -bas 12 separates, and filters the luminance signal from the color emptied signal of the SECAM system, and the luminance signal thus separated is applied to a frequency modulator 13 by means of a pre-emphasis circuit 14. frequency 13 frequency modulates a carrier of predetermined frequency using the luminance signal, and the luminance signal thus modulated in output frequency is applied to a recording amplifier 17 after its undesirable low frequency component has been eliminated in a high pass filter 16.

 The bandpass filter 13 separates, and filters, a signal carrying an on-line sequential chrominance obtained by alternating in frequency, two signals carrying predetermined frequencies using two types of color difference signals, from the SECAM color video signal. The on-line sequential chrominance carrying signal is then applied to a 1/4 down-counting circuit referenced 20, via an equalization circuit 18 and a limiter circuit 19 having predetermined characteristics. by chrominance carrier is reduced, by upcounter circuit 20, to 1/4 of the original frequency, and the bandwidth becomes equal to 1/4 of that of the input chrominance carrier signal. Thus, a chrominance-carrying signal, converted into the low band and having a frequency band which is converted into a lower band, is obtained at the output of the circuit counting down from 1/4. The chrominance carrier signal thus converted into the low band is applied to an equalizer circuit 22 by means of a low-pass filter 21. The low-pass filter 21 eliminates the undesirable high-frequency component. The equalizer circuit 22 is provided to correct the level attenuation introduced in the respective upper and lower lateral bands due to the above frequency reduction (division) effected by the down-counter circuit 20 by 1/4. The output signal from the equalizer circuit 22 is applied to the recording amplifier 17. The frequency modulated luminance signal from the bandpass filter 16 and the chrominance carrier signal converted into the low band from the equalizer circuit 22 which occupies a band lower than that of the luminance signal modulated in frequency are multiplexed by the recording amplifier 17. The multi plexed signal thus obtained is recorded on a magnetic tape 29 by a rotary head 28.

 In general, and as illustrated in fig. 2, a signal carrying chrominance from the SECAM system and which is referenced 45 is not transmitted during a stop before T2 nor during an interval T3 comprising part of the width of the horizontal synchronization pulse and a reverse stop, at l inside the horizontal blanking period T1. In addition, the chrominance carrying signal is also not transmitted during the time intervals corresponding to the number of horizontal scan lines 624 to 6, 16 to 22, 311 to 319 and 329 to 335, as illustrated in Figs. 3 (A) to 3 (D), in the vicinity of the vertical blanking period. Figs. 3 (A) 3 (B), 3 (C) and 3 (D) respectively show the vertical blanking period of the first, second, third and fourth frames. In each of the above figures, the parts of the turkey shape indicated by oblique lines correspond to a discrimination signal. Thus, if a limiter circuit of high sensitivity is used for the limiter circuit 19, or a flip-flop for the down-counter circuit 20 of 1/4, noise is introduced inside the interval of non-transmission of the carrier signal. chrominance during which the chrominance carrying signal is not transmitted.

 Thus, because the high frequency component of the luminance signal is included inside the output signal of the bandpass filter 13 in addition to the chrominance carrier signal, the high frequency component is emphasized at the same level as the carrier signal chrominance as noise if a high sensitivity limiter circuit is used for the limiter circuit 19. In addition, during duplicated reproduction or recording, the reproduced noise is a problem. Furthermore, if a flip-flop is used for the down-counter circuit 20 of 1/4, the erasing period becomes long. In addition, in the case where the level of the high frequency component of the luminance signal obtained at the output of the bandpass filter 13 above is sufficiently high to actuate the flip-flop, an undesirable noise component exhibiting the same level as the signal chrominance carrier is then introduced at the outlet of the scale.

 If the above noise component passes through the equalization circuit 22 (or an equalization circuit 41 provided in a reproduction device described below), the chrominance carrying signal is attenuated, and the noise component is accentuated. Thus, in this case, the frequency modulated luminance signal, at the portion of the multiple signal to be recorded and reproduced, i.e. 1 where the above component is multiplexed, is attenuated.

 Consequently, in the known device, the luminance signal illustrated in FIG. 4 (A), which is obtained at the output of the low-pass filter 12, is applied to a circuit 24 do separation of the synchronization signal by means of a switch 23 which is connected to the side of a point contact R. The horizontal synchronization signal, illustrated in fig. 4 (B), is thus separated by the circuit 24 for separating the synchronization signal, and it is then applied to a monostable multivibrator 23. The ultivibrator monos table 23 is triggered by a rear edge (or a front edge) of the horizontal synchronization signal, and it produces pulses having a width a 1. The width a 1 of the pulses corresponds to an interval comprised between the above rear edge of the horizontal synchronization signal and the start of a front step of the signal horizontal synchronization of next input. fig. 4 (C) shows a charge and discharge waveform of a capacitor provided in the monostable multivibrator 23, while FIG. 4 (D) shows the output pulses of the monostable multivibrator 23.

 The output pulse of the monostable multivibrator 25 is applied to a monostable multivibrator 26 in order to trigger the latter by the trailing edge of the output pulse. As a result, the charge and discharge waveform of a capacitor provided in the monostable multivibrator 26 becomes as illustrated in FIG. 4 (E), and the controllable multivibrator 26 produces pulses having a width a 2 as illustrated in FIG. 4 (F). The width a 2 of the pulses is substantially equal to the rubber of the intervals T2 and T3 illustrated in FIG. 2.The pulse leaving the table multivibrator 26 is applied to a switching circuit 27 illustrated in FIG. 1 as a noise trigger. During an interval of time corresponding to the width a 2 of the output pulse of the monostable multivibrator 26 illustrated in FIG. 4 (F), the signal do output of the down-counter circuit 20 of 1/4 is grounded in the manner of an alternating current circuit via the switching circuit 27 in order to interrupt the transmission of this signal do output to the low pass filter 21. The noise component within the horizontal blanking period is thus eliminated.

 We will now describe the operation during reproduction or reading. The multiplexed signal described above, which is reproduced by the rotating heads 28 from the magnetic strip 29, is applied to a high-pass filter 31 and to a low-pass filter 32 through a pr * -arplifier 30. The Sut-pass filter 31 separates the frequency modulated luminance signal from the multiplexed signal which has been reproduced. Such a frequency modulated and separate luminance signal is applied to a frequency demodulator 34 by the intermediate of a limit circuit 33 which is provided to eliminate the amplitude deviation. The reproduced luminance signal is obtained | the output of the frequency demodulator 34, and this signal is applied to an amplifier 36 via a belly-low filter 33.

The low-pass filter 32 separates and filters the chrominance-carrying signal converted in the low band from the multiplexed signal which has been reproduced, and the signal thus separated is applied to a 4-fold multiplier circuit, referenced 39, via an equalization circuit 37 and a limiting circuit 38. The multiplier circuit 39 by 4 increases by four times the frequency of the chrominance-carrying signal converted in the low band and which has been reproduced. As a result, a reproduced chrominance carrier signal is obtained which has the same band karger and the same band as the original chrominance carrier signal. Such a reproduced chrominance carrier signal is applied to the amplifier 36 by 1. intermediary of a bandpass filter 40 and of the equalization circuit 41. The reproduced chrominance carrier signal and the reproduced luminance signal are multiplexed at the amplifier 36, and an output terminal 43 obtains a system color video signal
SECAM reproduced.

 If the noise component is introduced during the non-transmission interval of the chrominance-carrying signal, the noise component crosses the equalization circuit 41 and is multiplexed with the luminance signal reproduced at the level of the amplifier 36. In the present case, the multiplexing position corresponds to the part of the synchronization signal of the reproduced luminance signal. This leads to an erroneous operation of the circuit for separating the synchronization signal from the control television receiver, and vibrations of the reproduced image as well as desynchronization and other disturbing phenomena are introduced into the reproduced image. The synchronization of the television receiver thus becomes unstable.

In order to prevent the television receiver from being put in the above unstable state during reproduction, the luminance signal reproduced coming from the frequency demodulator 34 is first of all caused to pass through. the coatsiutator 23 which is connected on the side of a contact point
P. The luminance signal reproduced from the switch 23 is applied to the circuit 24 for separation of the synchronization signal in which the horizontal synchronization signal is separated. Such a horizontal synchronization signal then passes through the monostable multivibrators 23 and 26, as during recording, and it is transformed to give a pulse illustrated in FIG. 4 (F).

 The above pulse is applied to a switching circuit 42 to ground this circuit. Consequently, the transmission of the reproduced chrominance carrier signal or the noise component to the high-pass filter 40 from the multiplier circuit 39 by 4 is interrupted during the interval a 2 above. Such an arrangement was the measure taken to avoid the instability of horizontal synchronism due to the above noise component.

 However, as illustrated by the intervals T2 and T3 in FIG. 2, the interval during which the chrominance-carrying signal is not transmitted within the horizontal erasure period is only about 7 msec. Consequently, in the known device described previously, the trailing edge of the output pulse of the monostable multivibrator 23 having the pulse width a 1 must fall within the interval T2 (substantially within of 1 Asec). In addition, the trailing edge of the output pulse of the monostable multivibrator 26 having the pulse width a 2 must also fall within the interval in which the chrominance-carrying signal is not transmitted (substantially 0 , 7 tec) in the rear landing following the horizontal synchronization pulse. However, as described above, the above rear edges will not fall inside the previous intervals, even if the rhythm is offset by 1 * because the delay times of the monostable multivibrators 23 and 26 above are important. There was thus a drawback in that the operation of adjusting the time constants of the monostable multivibrators 25 and 26, so as to adjust the pulse widths a 1 and a 2, had to be carried out with extremely high precision.

 The present invention has eliminated the above drawback of the prior art, and an embodiment of the present invention will now be described in connection with Figs. 5 to 7.

 Fig. 3 is a block diagram illustrating an embodiment of the present invention. In FIG. 3, the elements which are the same as the corresponding elements of FIG. 1 are designated by the same references and are not described in detail in the following. A description is first given of the operation during a recording.

 The SECAM color video signal applied to the input terminal 11 is supplied to a low-pass filter 51 and to the band-pass filter 13, and it is also applied to a low-pass filter 53 via a switch 52 which is connected on the side of a contact point R during recording. The low-pass filters 31 and 33 respectively separate and filter the luminance signal from the color video signal of the SECAM system. The low-pass filter 31 has a sharp characteristic in order to separate and filter the luminance signal with great precision, and the envelope delay time is adjusted to a low value of the order of 1.5 sec to 1, 2 sec in the low band. In addition, the envelope delay time of the low pass filter 35, provided in the reproducing device described below, is set to an analogous value. Furthermore, the envelope delay time of the low-pass filter 53 is set to an excessively low twist value of 0.2 with at 0.3 sec taking into account the position where the triggering of the noise begins at within the horizontal erasure period. The luminance signal from the low-pass filter 31 is thus delayed by about 1 tAec with respect to the luminance signal from the low-pass filter 53.

 The luminance signal obtained from the low pass filter 53 is applied to a synchronization signal separation circuit 54 in which a composite synchronization signal is separated. Thus, with respect to an input signal in the vicinity of the vertical blanking period of the luminance signal illustrated in FIG. 6 (B) and which is obtained from the low-pass filter 53, the circuit 54 for separation of the synchronization signal separates and produces equalization pulses, vertical synchronization pulses and the other illusive pulses sorted in FIG. 6 (C).

Fig. 6 (A) illustrates the number of lines. horizontal sweep. The composite synchronization signal thus separated is applied to a re-triggerable single-table multivibrator 59 in order to trigger the single-table multivibrator 95 by the leading edge of the composite synchronization signal indicated by B (1) in FIG. 6 (C). Thus, the charge and discharge waveform of a capacitor provided in the multivibrator table 35 monos becomes as shown in FIG. 6 (D), and the output pulse of the monostable multivibrator 33 drops after a predetermined time interval a # until a threshold level, indicated by a dashed line in FIG. 6 (D), either exceeded
The predetermined time interval a 3 is chosen to be between 0.5H and 1H, where H indicates a horizontal scanning period of 64 rsec. As illustrated in fig. 6 (D), during a time interval in which the equalization pulses and the vertical synchronization pulses are deprived, the charge and discharge waveform of the capacitor provided in the monostable multivibrator 33 does not exceed the level Thus, the output signal of the table 55 single-multivibrator remains high and the result is that the output pulse crosses as shown in FIG. 6 (E).

 If the table mono multivibrator 35 is triggered by the trailing edge of the composite synchronization signal indicated by B (2) in fig. 6 (C), the output pulse will drop to a position indicated by C (1) in fig. 6 (B), immediately after the position where the vertical synchronization signal begins. Therefore, the monostable multivibrator 55 cannot be triggered by the trailing edge of the composite synchronization signal.

 The pulse illustrated in fig. 6 (E), which is thus obtained from the monostable multibrator 53, is applied to a monostable multivibrator 36 which can be timed with a greater time constant than that of the monostable multivibrator 35. The mono-table multivibrator 56 is triggered by the rear edge of the monostable multivibrator 35 output signal indicated by D (1) in fig. 6 (E). The charge and discharge waveform of a capacitor provided in the monostable multivibrator 36 thus becomes as illustrated in FIG. 6 (F), and the output pulse of the monostable multivibrator 56 comes from a high level when a threshold level indicated by a dashed line in FIG. 6 (F) is exceeded. The monostable multivibrator 56 is reset to zero by the trailing edge of the output pulse from the monostable multivibrator 33. Consequently and as illustrated in FIG.

6 (G), the output pulse of the monostable multivibrator 56 is a pulse which is of high level for more than an interval of 1H between the vertical synchronization pulses. In fig. 6 (G3 an interval a 4 is chosen equal to a value greater than the pulse width a 3.

 The pulse illustrated in fig. 6 (G), which is obtained from the monostable multivibrator 36, is applied to a switching circuit 58 via a mixer circuit 37. During the period of high level of the pulse from the monostable multivibrator 56, the output end of the equalizing circuit 22 is grounded in the manner of an alternating current by the switching circuit 38. Thus, coming from the chrominance-carrying signal converted in the low band and which is applied to the recording amplifier 17 from the equalizing circuit 22, the vertical synchronization pulse and the signal having a duration greater than 1H in the vicinity of the vertical synchronization pulse are not transmitted, so that the noise component within this interval is eliminated.

The noise component within the non-transmission interval of the chrominance-carrying signal in the vicinity of the vertical blanking period can thus be eliminated in a device for transmitting the chrominance-carrying signal converted into the low band. In addition, the time constant of the table 55 multivibrator above is determined so that the pulse width a 3 takes a value between 0.5H and 1H. In the pre case
feels 0.5H equals 32 sec, and therefore it is easy to adjust the pulse width X 3 so that it
falls inside of these 32 vsec, which means that
the setting of the time constant can be done roughly, similarly the constant of
time of the monos table multivibrator 36 can be roughly performed, because only the condition that a 4 is greater than the pulse width 3 needs to be satisfied. As a result, even if there are fluctuating
tions in the time constants of the monostable multivibrators 33 and 36, this causes only a fluctuation in output of the order of a few seconds at most, and the circuit thus requires no adjustment.

We now describe the elimination of the noise component within the horizon erasure period
tal in a device for transmitting the chrominance-carrying signal converted into the low band. As illustrated in fig. 7 (B), the luminance signal obtained at the output of the low-pass filter 51 is delayed by a predetermined time interval 1 # with respect to the luminance signal illustrated in FIG. 7 (1) inside the SECAM input color video signal applied to the input terminal
trée 11. Such a luminance signal is illustrated in FIG.

7 (B) and is applied to a circuit 61 for separating the synchronization signal, in which the horizontal synchronization signal is separated, by means of a switch 60 which is connected from the side of a contact point
R when recording. The horizontal synchronization signal thus separated has a waveform illustrated in FIG. 7 (D), and it is applied to the mixer circuit 57 after being delayed by a predetermined time interval d2 and transformed into a signal illustrated in FIG. 7 (F) at a delay circuit 62.

Furthermore, as illustrated in FIG. 7 (C), the luminance signal obtained at the output of the low-pass filter 53
is subject to a relative delay of approximately 1 sec per rap
port to luminance signal from low pass filter
illustrated in fig. 7 (B), as previously described. The
luminance signal from the low-pass filter 53 is applied to the circuit 54 for separation of the synchronization signal in which the synchronization signal is separated
The horizontal synchronization signal illustrated in fig. 7 (E), which is obtained from the circuit 54 for separating the synchronization signal, is applied to the mixer circuit 57 above. The horizontal synchronization signal illustrated in fig. 7 (E) and the horizontal synchronization signal illustrated in fig. 7 (r), which is obtained from the delay circuit 62, are mixed at the level of the mixer circuit 57 to produce the pulse illustrated in FIG. 7 (G). Such an output pulse is applied to the switching circuit 38 to ground the output end of the equalizing circuit 22 in the manner of an alternating current during the high level interval of the 'output impuslion.

 The frequency modulated luminance signal which is applied to the recording amplifier 17 is a signal obtained by frequency modulating a carrier wave with the delayed luminance signal illustrated in FIG. 7 (B), and the rhythm of this signal must coincide with that of the chrominance-carrying signal converted in the low band.

The output end of the equalizer circuit 22 is set to
the mass during the time interval between approx.
ron 1 disse before horizontal synchronization pulse
and approximately 0.7 sec after the horizontal synchronization pulse, that is to say 1 t interval, within the horizontal erasure period of non-transmission of the signal. chrominance carrier converted to the low band.

Thus, the above noise component is eliminated
The position and width of the trigger pulse
noise noise within the horizontal erasure period, illustrated in fig. 7 (G), are determined by
the delay times of the low-pass filters 31 and 33 and of the delay circuit 62. These delay times are of excessively low value and less than about 1.5 sec, and, for this reason, a certain deviation in these times of delay is not harmful. It therefore becomes possible to make a circuit which does not require any leveling.

 The operation of the device during a reproduction will now be described. During a reproduction, the switches 52 and 60 are both connected on the side of a contact point P. The luminance signal reproduced from the frequency demodulator 34 is applied to a low-pass filter 53 via the switch 32.

Furthermore, the reproduced luminance signal, which has been delayed more by about lksec than the reproduced luminance signal applied to the low-pass filter 33, is applied to the circuit 61 for separation of the synchronization signal via the switch 60. In the same way as previously described in connection with the recording device, the output signal of the mixer circuit 37 is applied to a switching circuit 39 to ground this circuit 39. Thus, the noise component, introduced inside the horizontal erasure period and in the vicinity of the vertical efftceoent period where the chrominance-carrying signal is not originally transmitted, is eliminated by the circuit switch 39 provided in the chrominance carrying signal transmission device.

 The impulse (this impulse is equivalent to the impulse illustrated in fig. 6 (G3) allowing the elimination of the noise component in the vicinity of the vertical erasure period during reproduction is produced in synchronism with the reproduced composite synchronization signal.

Thus even if the time base deviation of the reproduced signal is large, as is the case in a portable type magnetic tape recording and reproducing apparatus, there is an advantage in that the deviation is obtained in synchronism with this time base deviation.

 Fig. 8 shows a block diagram of an essential part of another embodiment of a device according to the present invention. In fig. 8, the elements which are the same as the corresponding elements of FIG. 3 are designated by the same references and are not described in detail in the following. In the present embodiment, a delay circuit 63, making it possible to delay the composite synchronization signal leaving the circuit 34 for separation of the synchronization signal, is provided in place of the circuit element comprising the switch 60, the circuit 61 for separating the synchronization signal and the delay circuit 62 illustrated in FIG. 5.The pulse illustrated in fig. 7 (G) can thus be obtained at the outlet of the mixing circuit 97. In the present embodiment of the invention, the circuit can be simplified compared to the embodiment illustrated in FIG. 3.

 In the device according to the present invention, the recording and the reproduction are carried out by interrupting the output of the device for transmitting the signals carrying chrominance during the interval, within the horizontal erasing period, not transmission of the chrominance-carrying signal, and the delay time of the low-pass filters is used so that the need to adjust the circuit is eliminated. It is therefore not essential to trigger the noise in the vicinity of the vertical erasing period. The present invention is also not limited to the embodiments shown and described in detail, because various modifications can be made without departing from its scope.

Claims (9)

 1 - Device for recording color video signals from the SECAM system in which a luminance signal is separated by a first filtering circuit (12, 51) and a chrominance carrying signal is separated by a second filtering circuit (13) , from the SECAM color video signal, the luminance signal is frequency modulated, the chrominance carrying signal is converted into a band lower than that of the frequency modulated luminance signal and the frequency modulated luminance signal and the chrominance carrier signal converted in the low band are multiplexed and recorded on a recording medium (29), the device being characterized in that it comprises a third filtering circuit (33) receiving the color video signal from the SECAM system in order to separate and filter the luminance signal with a delay time relatively shorter than the delay time of the first filter circuit, a pulse forming circuit (34, 63, (or 60-62 ), 37) to form a pulse having an i-pulse width corresponding substantially to an interval between a time when there is a horizontal synchronization signal input of the luminance signal from the third filter circuit and a terminal position of a interval of non-transmission of the chrominance-carrying signal within the period of horizontal erasure of the luminance signal coming from the three seat filtering circuit, and a first switching circuit (38) receiving the pulse originating from of the pulse forming circuit in order to interrupt the transmission of the chrominance carrier signal converted in the low band to first mixing means provided for mixing the frequency modulated luminance signal and the chrominance carrier signal converted in the low band during a time interval corresponding to the pulse width from the pulse forming circuit.  2 - Recording device according to claim 1, characterized in that the pulse forming circuit comprises a first circuit (61) for separating the synchronization signal in order to separate a horizontal synchronization signal from the luminance signal obtained from of the first filter circuit, a delay circuit (62) for delaying the horizontal synchronization signal from the first circuit for separating the synchronization signal so that the position of a trailing edge of the horizontal synchronization signal corresponds substantially to the position terminal of the non-transmission interval of the chrominance-carrying signal within the period of horizontal erasure of the luminance signal originating from the first filtering circuit, a second circuit (g4) for separating the synchronization signal allowing to separate a horizontal synchronization signal from the luminance signal obtained at the output of the third wire circuit trage, and a mixing circuit (37) for mixing the output signals of the first and second circuits for separating the synchronization signal.  3 - Recording device according to claim 1, characterized in that the pulse formation circuit comprises a circuit (34) for separation of the synchronization signal - in order to separate a horizontal synchronization signal from the luminance signal obtained at the output of the third filtering circuit, a delay circuit (63) making it possible to delay the horizontal synchronization signal leaving the circuit for separating the synchronization signal so that the position of a trailing edge of the horizontal synchronization signal corresponds substantially to the end position of the interval of non-transmission of the chrominance-carrying signal within the period of horizontal erasure of the luminance signal originating from the first filtering circuit, and a m4-languer circuit (roi7) provided for mixing the signals horizontal synchronization output of said separation circuit of the synchronization signal and the delay circuit.  4 - Device for recording and reproducing color video signals of the SECAM system comprising the recording device according to claim 1, characterized in that a fourth filtering circuit (33) having a time is also provided relatively greater delay than that of the third filter circuit in order to obtain a luminance signal reproduced from an output of a frequency demodulator which demodulates in frequency the frequency modulated luminance signal reproduced from the medium d recording, a second switching circuit (52) making it possible to apply the output of the frequency demodulator to the third filtering circuit during reproduction, and a three seat switching circuit (39) receiving the impulse coming from the training circuit of pulses in order to interrupt the transmission of a chromium-carrying signal reproduced and restored to the original band to second filtering means provided for mela nger the luminance signal reproduced from the fourth filter circuit and the chrominance carrying signal reproduced and restored to the original band for an interval equal to the pulse width of the pulse from the pulse forming circuit and corresponding appreciably to an interval between a time when there is a horizontal synchronization signal input of the lumenance signal coming from the third filtering circuit and a terminal position of an interval of non-transmistion of the chrominance-carrying signal within a period of horizontal erasure of the luminance signal reproduced from the fourth filter circuit.  3 - recording and reproducing device comprising the recording device according to claim 2, characterized in that there is further provided a fourth cosutation circuit (60) allowing, during reproduction, to apply the reproduced luminance signal leaving the fourth filter circuit to the first circuit for separating the synchronization signal.  6 - recording and reproducing device according to claim 4, characterized in that there is provided a circuit (54) for separating the synchronization signal in order to separate a composite synchronization signal from the luminance signal obtained at the output of the third filter circuit, a first monostable multivibrator (33) triggered by the composite synchronization signal obtained from the separation circuit of the synchronization signal in order to produce a pulse having a selected pulse width at an interval shorter than a period of horizontal sweep and longer than half a horizontal sweep period, and a second monostable multivibrator (36) triggered by the output pulse of the first single-table multivibrator to produce a pulse after an interval has elapsed greater than the pulse width of the output pulse of the first onostable multivibrator, the output pulse of the second m mono table ultivibrator being applied to the first or third switching circuit to interrupt the transmission of the chrominance carrier signal converted in the low band or of the chrominance carrier signal restored to the original band, for an interval in the vicinity of the erasure period vertical  7 - Device for recording and reproducing according to claim 6, characterized in that the first and second monostable multivibrators (55, 56) are stable mono re-ignitable multivibrators  8 - A recording and reproducing device according to one of claims 6 or 7, characterized in that the first monostable multivibrator (35) is triggered by a leading edge of the first composite synchronization signal.  9 - Recording device according to claim 1, characterized in that the means making it possible to convert the chrominance-carrying signal separated by the second filtering circuit into a band lower than that of the luminance signal modulated in frequency comprise a limiting circuit ( 19) in order to limit the amplitude of the chrominance carrying signal obtained from the second filtering circuit and a countdown circuit (20) making it possible to divide the frequency of the output signal from this limiter and thus to reduce this frequency.