NO841153L - SYSTEM FOR COLOR REMOTE SIGNALS, SPECIFICALLY OF THE SECAM TYPE, IN A RECEIVER DEVICE FOR SUCH SIGNALS - Google Patents

Description

The invention relates to a system for processing color television signals, in particular of the SECAM type, which are supplied to a receiving device, such as a color television receiver,

a control monitor or similar, the system comprising means for generating auxiliary carrier waves for the chrominance signals and the carrier wave for the luminance signal.

The conventional systems for processing chrominance and luminance signals, of the SECAM type, are based on the use of two color auxiliary carrier waves of 4.406 and 4.25 MHz, respectively, which alternately transmit the chrominance signals D i\ for one line and the chrominance signals D D for the subsequent line. The auxiliary carrier waves are frequency modulated. For this purpose

the chrominance signals are fed to a modulator stage by means of an electronic switch. Before the chrominance signals are mixed with the luminance and sync signals, they are fed to an "anti-clock curve" type band-limiting filter which reduces the background noise. The signals are then transmitted to the receiving device, for example by means of a cable. The receiving device comprises a decoder necessarily equipped with clock filters, with a branch between a path delayed by one line duration, and a direct path, and with an inverter driven by a flip-flop or flip-flop which is synchronized by the line synchronization signals to switching the received chrominance information into an auxiliary carrier wave path for the information D_K and an auxiliary carrier wave path for the information D ; and a gate device which closes the auxiliary carrier wave paths in the absence of color difference signals written from the identification lines, correcting untimely operation of the flip-flop.

From the composite video signal E'v and from the color difference signals Dn = (E'_ - E' ) and Dn = (E' - E' ) provided by the decoder, matrix forming circuits and video circuits reconstruct the three color signals E' D , E 'K

and E'v which are necessary for the modulation of the picture tube.

These known systems suffer from a certain number of disadvantages. For example, one can observe an imperfection in color sharpness due to the fact that the chrominance information transmission passband is of the order of 300 kHz, and is therefore very small and completely insufficient for a suitable color sharpness and does not allow the transmission of one or more coded binary words, f .ex. in "N.R.Z." (non-return to zero) mode. In such systems, the chrominance signals are also exposed to a relatively significant number of operations, which each time results in a loss of information. For example, such losses of information are caused by the delay lines used in the decoder, and a reduction of the vertical sharpness of the chrominance occurs, due to each information being transmitted only under one of two lines.

The purpose of the present invention is to remedy the above-mentioned disadvantages.

For this purpose, the invention relates to a system for processing color television signals, in particular of the SECAM type, comprising a device, such as a color television camera, for sending chrominance auxiliary carrier wave signals and a luminance signal to a receiving device, such as a color television receiver, a control monitor or similar, the receiver device comprising a device for decoding the received video signals, which system is characterized in that the decoder device comprises first and second tuned circuits which each receive a chrominance auxiliary carrier wave signal, the first tuned circuit being connected to a discriminator which produces the color difference signal (E1 - E1 ) while the second tuned circuit is coupled to another discriminator which produces the color difference signal (E' - E' ), and a third tuned circuit which receives the luminance information signal E'Y and is coupled to a discriminator which provides the DC component of the luminance signal, the output signals Fr a the first, second and third discriminators are supplied to a matrix forming circuit to produce the color signals E', E* and E'B, the three discriminators at the beginning of each line being synchronized on the same clock signal. According to another feature of the invention, the clock signal is derived from the clock that receives the output signals from the line and full-frame or partial-frame time base in the picture tube's control circuit. According to another feature of the invention, the clock signal is the high-frequency signal derived from the main clock in the transmitter device. The invention will be better understood, and other purposes, features and advantages of it will appear more clearly from the following detailed description with reference to the schematic drawings which illustrate several embodiments of the invention solely as an example, and where fig. 1 shows a block core of the video information signal transmitter device, fig. 2 shows a block core of an anti-copying device, fig. 3 schematically illustrates the signal for identification of the control of the function of the electronic switch in a SECAM receiver, and the signals used for determining the time of presence of said identification signal, fig. 4 illustrates the location of the synchronization pulses which are constituted by bursts or series of anticopy oscillations, FIG. 5 shows a block diagram of a video information signal receiver device according to the invention, and fig. 6 shows a block diagram of an anti-copy signal decoder circuit. In the one in fig. 1 shows the transmitter device, 1 shows a recording or filming device which consists of a color television camera, and 2 shows the device with the three matrices which produce the chrominance signals at their outputs, i.e. f argedifference signals D_, = E' - E', D_. - E' - E' ;K K x B B x , and the luminance signal E'Y of the SECAM type. The device comprises three voltage-controlled oscillators 3, 4 and 5, suitably of the quartz crystal type, the oscillators 3 and 5 being calculated for generating the auxiliary carrier wave frequencies for the chrominance signals D_R . respectively B, while the oscillator 4 generates the luminance signal carrier. Oscillators 3 and 5 are arranged to produce auxiliary carriers with frequencies equal to a multiple of the SECAM system's conventional auxiliary carriers of 4.406 and 4.250 MHz. In this case, the ratio between the auxiliary carrier waves produced by the oscillators 3 and 5 is identical to the ratio between the aforementioned, conventional auxiliary carrier waves, in order to ensure the device's compatibility or compatibility with the conventional devices. The auxiliary carriers are of course frequency modulated with the signals D R and D B. As a result of the use of chrominance or color auxiliary carriers with a frequency that is a multiple of the frequency of the conventional auxiliary carriers, the data transmission passband is sufficiently wide to ensure a good sharpness of the colors and to allow the transmission of one or more binary words encoded for example in "N.R.Z." (non-zero return) mode, which is known per se and is used, for example, on the ANTIOPE teletext system. The subsequent processing applied to such frequency-modulated auxiliary carriers will also be limited to frequency division operations. ;As shown in fig. 1, the transmitter device comprises an anti-copying device 6. As can be seen from fig. 2, this essentially contains a keyboard 61 which allows a predetermined pulse to be selected by influencing e.g. one or more keys,°^a read-only storage (ROM) 62 whose function is to transform the information entered using the keyboard into a digital signal which appears, for example, in parallel at the storage's outputs. These outputs are connected to a group of parallel inputs to a multiplexer 63 which on the inputs of a second group receives the output signals from a voltage divider 64. Based on a clock frequency shown at 65, the voltage divider 64 produces either the same frequency on all these outputs, or different frequencies that are specific to each of the aforementioned outputs. At its output, the multiplexer 63 produces a sequence of bursts or series of oscillations with the same frequency or with different frequencies, which corresponds to the digital signal at the output of the read storage 62. This sequence of oscillation series is fed to a device 66 located in the track for the signals coming from the camera 1, 2. The task of the device 66 is to prevent the transmission of at least part of the identification signal which serves to control the phase of the electronic switch in the receiver device of the conventional SECAM type. The device 66 and the multiplexer 63 are controlled by a gate element 68. This gate has three inputs to which are supplied signals B, C and D which are shown in fig. 3. These signals are produced in the SECAM-type encoder and represent the port for the dual line frequencies, the full frame or partial frame and line identification location and the identification gate. At a in fig. 3 schematically shows the electronic switch's control identification signal which is at least partially replaced by the anti-copy oscillation series. It appears that the time of presence of the identification signal a is defined by the fact that the signals c and d are in the "l" state and the signal at b is in the "0" state. When reversing the signal b, the time for the presence of the identification signal a can therefore be determined by means of a gate and as shown in fig. 2. As regards the operation of the device just described, it should be noted that the anti-copying oscillations have a frequency that lies outside the passband reserved for the identification signal provided in the receivers of the conventional SECAM type. It is possible to register the signals produced by the camera 1, 2, for the first time, for example on a magnetic tape. However, if one wished to produce a second recording of this first recording, i.e. a copy, the quality of the latter would be insufficient and would result in a reproduction or reproduction of poor quality, because during the reproduction of the copy, the correct operation of the SECAM - the switch is not secured. As for the frequency of the anticopy oscillations, this may conveniently be the same frequency as the oscillations produced by the auxiliary carrier and carrier oscillators 3, 4 and 5 whose frequency is equal to a multiple of the frequency of the conventional SECAM auxiliary carriers. It follows from the preceding considerations that the introduction of an anti-copying code consisting of bursts or series of oscillations with a frequency that lies outside the passband of the conventional receivers, in the sequence of signals provided by the camera or by any other source of color television signals, interfere with any fraudulent or improper registration activity. The presence of the anti-copy code signals in the original signal sequences and thus on the original recording medium also makes it possible to ensure that the recording is an original recording and not a copy. It should also be noted that the aforementioned anti-copying device is designed to allow connection to an external device. For this purpose, an input 69 is provided which is linked to a processing unit 70 which, if appropriate, cooperates with and is active together with the keyboard 61 and the read storage 62. It should also be noted that the anti-copying device also allows the entry of numbers or numbers that allow identification of the latter. Referring to fig. 2, the anti-copying device 6 contains another device or circuit 71 which allows the completion of an anti-copying function. As can be seen from fig. 4, which shows an oscillogram of one and the same line corresponding to the bar or bar pattern for 75% amplitude for the colors white, yellow, teal, magenta, red, blue and black (from left to right), each signal occurs at A, B, and C of a synchronization pulse 72 which extends below the possible minimum levels of each signal. The device 71 is now arranged to produce synchronization pulses 72 from a series of oscillations with a frequency that lies outside the pass-band frequency in the conventional SECAM receiver devices. These oscillations can be the auxiliary carrier waves produced by the oscillators 3, 5 with a frequency that is a multiple of the conventional SECAM auxiliary carrier wave frequencies. The device 71 may be constituted by any suitable circuit capable of performing, for example, the function of a two-input AND gate arranged to receive respectively a synchronization gate pulse and, at 73, oscillation series. In the latter case, due to the fact that the anti-copying oscillations are outside the passband of the receiving device, the copies produced from the first recording will not allow a good quality reproduction or reproduction due to a loss of synchronism that increases rapidly from copy to copy . The transmitter device shown also contains three analog/digital converters 10, 11, 12, each of which is intended for processing one of the three signals D_., DD and E'. Each converter ;KB x ;is connected to the output of one of the three matrices in the television camera, either by means of a device 7 or by intermediate connection of the anti-copying device 6. On the downstream side of each converter 10-12 is shown a respective switching circuit 13, 14 and 15 which connects the converter to which it is connected with an output data bus 17, 18 and 19, either directly or via an interference or disturbance eliminating device 20, 21, 22. When the digital signals in binary code produced by the corresponding analog-to-digital converter 10, 11 or 12, on each bus is present in accordance with a parallel constellation, for each of the data buses a parallel-to-serial converter 24, 25 or 26 is provided for transforming the parallel constellation into a constellation of signals in series. ;Each a<y>th disturbance eliminating devices ;20, 21 and 22 comprises a processing unit 27, such as a microcomputer or microprocessor, two RAM stores 28, 29 ;for storing the complete partial image or full image produced by the camera, and the preceding full image or partial image, as well as a ROM storage 30 which contains the processing unit's routine. The latter can also be programmed to ensure the generation of a very stable DC supply voltage, by means of a digital/analog converter device 31, based on a previously defined binary digit. This DC voltage can serve as a reference voltage for the supply system for the various elements of the treatment device, in particular for producing the supply for the oscillators 3, 4 and 5, in the manner described. This voltage is available on the output seed 32. The disturbance eliminating device may also be provided with a device known per se which allows the correction of errors contained in the digital signals relating to several binary elements, for example by ensuring the presence of a predetermined number of binary states in each digital signal. The processing device 27 allows the fulfillment of this in and of itself known function. The processing unit can also be arranged to produce a signal indicating the absence of errors in the digital signals. ;When it comes to the cooperation between the analog/digital converters 10-12 and the anti-copying device, it should be noted that the anti-copying codes may already be introduced in the sequence of chrominance and luminance signals in digital form. In this case, the anti-copying device 6 will ensure suppression of the converters during the corresponding time intervals, i.e. it will cause free passage through the converters of the sequence parts occupied by this code. To ensure perfect synchronization of the operation of the various elements in the transmitter device, this contains a quartz crystal-controlled oscillator 34 which forms a generator for high-frequency signals, e.g. of the order of 100 MHz. This oscillator fulfills the function of a master clock. As can be seen from the figure, the line and field and half-line synchronization signals available at 35 are derived from the master clock. The analog/digital converters 10-12, the parallel-series converters 24-26 and the disturbance eliminating devices 20-22 are also controlled by the clock. The conductors for the clock signals for controlling these elements are shown at 36, 37 and 38 respectively. At 39 the main clock 34 supplies the synchronization signals for the auxiliary carrier wave and carrier wave generating oscillators 3, 4, 5. The synchronization of these oscillators is thus ensured by the fact that the synchronization signals are derived from one and the same high-frequency signal. It should be noted that all synchronization and reference signals are obtained by dividing the clock signal frequency, so that a perfect stability of the thus obtained signals is ensured, and a perfect frequency and phase synchronism of the oscillators 3, 4 and 5 and of the signals, i.e. of their leading edge, as well as of all the operations performed by the treatment system according to the invention. To ensure the stability of the clock oscillator's 34 frequency, e.g. in order to prevent possible thermal operation, the aforementioned oscillator is inserted in a stabilizing loop (not shown) which also contains the oscillators 3, 4 and 5. supply voltages for the auxiliary carrier and carrier generating oscillators 3, 4 and 5. These voltages are available at the output terminals 41 of the supply device. As schematically shown in the figure, the device for generating the supply voltages for the oscillators is suitably derived from the high frequency clock signal produced by the main clock 34. The supply device 40 receives at 42 this clock signal of, for example, 100 MHz. In the device 40, this signal is divided by means of a frequency divider which is schematically shown at 43 and which, based on this, produces a signal of, for example, 1 MHz. This is fed to a saturated amplifier 44 which operates in the off-on mode and which is itself fed with the very stable direct voltage produced at 32 by one of the pre-rotating devices 20, 21 or 22. A converter 45 converts the amplifier's output signal to a direct voltage which is available at the outputs 41. This voltage is completely stable as a result of it being derived from the clock frequency by means of frequency division, which in itself already ensures a high degree of stability, and from the very stable voltage produced of the interference-eliminating devices based on a binary digit. The amplitude of the output voltage is thus precisely controllable. It should also be noted that the supply device 40 is galvanically separated from the supply mains voltage by means of a transformer (not shown). Referring to fig. 1, it appears that the processing device on the output terminals 48-50 produces output signals from the oscillators 3, 4 and 5, i.e. the auxiliary carrier waves which are modulated with the chrominance signals, and the carrier wave which is modulated with the luminance signal. Output terminals 51, 52 and 53 are provided from which the chrominance and luminance signals as produced by the color television camera can be taken. The system also contains output terminals 55, 56 from which the high-frequency clock signal produced by the oscillator 34 and the line and full-image or partial-image and half-line synchronization signals can be taken. The reference numbers 58-60 denote the output terminals for the data buses 17-19, while the digital signals in series constellation are available on the terminals 61-63. The no-fault signal is present at the output 64. Terminals 65 and 66 are connected to the supply device 40 and denote the earth and supply potential. ;All of the aforementioned outputs or at least ;a substantial part of them may be connected to a connector of the multi-pin type which may be connected to a receiving device, such as, for example, a conventional color television receiver, a monitor for visual control and the like. By also providing a connector, for example of the multi-pin type, on the input side, a system can be obtained which constitutes an independent unit which can be installed between a color television camera and a suitable receiving device. However, it is also possible to insert this device together with the camera and the receiving device, such as a video tape recorder, in the same casing to thus achieve a kind of remote film system, a set of film copies or of any documents. The operation of the transmitter device is immediately apparent from the preceding description and from the figure. It is therefore not necessary to describe this, apart from the operation of the interference-eliminating devices. Each of these works in the following way. In order to eliminate the disturbances, the processing unit 27, under the control of the routine stored in the read storage, compares each full image or partial image with the previous full image or partial image. These full images or partial images are stored in the RAM stores 28, 29. As a result of this comparison operation, all the image elements common to both partial images are preserved. On the other hand, the non-identical elements are eliminated. It should be noted that the two partial images are shifted in time by 20 ms. The elements that represent disturbance are therefore usually no longer the same i-berg partial images. By appropriate, relatively simple programming, the processing unit can be adapted to distinguish a difference in the two partial images, produced by an object moving in front of the camera, from a difference caused by disturbance. In reality, the wandering object retains its general outline, i.e. the pictorial elements that represent it, mainly retain their shape. They just change places in the two partial images. This non-change of the general shape of the image elements, which represent an object in motion from one sub-image to the subsequent sub-image, allows the discrimination of disturbance which is of a random nature and therefore in principle always different from one sub-image' to the other. It is easy to realize that the interference-eliminating device can be made even more advanced and sensitive to special parameters by connecting it to an external computer that is programmed accordingly. The transmitter device as shown in fig. 1 and described above, can of course be modified in various ways. Thus, the chrominance and luminance signals do not need to be taken at the output of the camera. They can come from any other transmitting device. One can also imagine the possibility that the auxiliary carrier-generating oscillators 3 and 5 are not supplied with the chrominance signals in their analog form, but in their digital form obtained at the outputs of the analog/digital converters 10-12, and, if there is appropriate, after the treatment by means of the disturbance eliminating devices. In this way, output signals that are freed from random interference would be obtained. It must again be emphasized that the choice of the carrier frequencies must be made in such a way that all the derived information and signals can be transmitted and processed so that they exhibit good sharpness, and so that they are preserved in their original state without practically undergoing any deterioration. The system may allow transmission of digital signals in any suitable code, e.g. of signals by N.R.Z. (non-zero return) type, such as the signals used for the ANTIOPE system. Fig. 5 shows the receiver device which constitutes the object of the present invention and which is used for the processing of the chrominance and luminance information signals which are obtained at the outputs of the transmitter device. The chrominance sub-carrier signal D as available at the output terminal 48 of the transmitting device is applied directly to the input terminal 48' of a bell circuit 80 or a circuit tuned to the sub-carrier frequency, i.e. 4.406 MHz, and which allows obtaining a auxiliary carrier signal with as constant an amplitude as possible. The output of the clock circuit 80 is connected to a discriminator circuit 81 which demodulates the color difference signal D which is frequency modulated and tuned to the auxiliary carrier's rest frequency of 4.406 MHz. The demodulated signal is post-corrected in the post-correction circuit 82 and supplied to a matrix 84 via an amplifier 83 to reconstruct the color signal E' from E'y and (E'B - E'y). The chrominance subcarrier signal DD ri as available at the output terminal 50 of the transmitting device is applied directly to the input terminal 50' of a bell circuit 90 or a circuit tuned to the subcarrier frequency (4.250 MHz). The output of the clock circuit is connected to a discriminator circuit 91 which demodulates the frequency modulated color difference signal D which is tuned to the rest frequency of the auxiliary carrier, i.e. 4.250 MHz. The demodulated signal is post-corrected in the post-correction circuit 92 and transferred to a matrix 94 via an amplifier 93 to reconstruct the color signal E1 r> from the signals E1 Y and (E' ti - E' Y). ;As known per se, a matrix ;95 allows the reconstruction of the color difference signal (E' - E'v) from the signals (E<*>K - E' Y ) and (E' ri - E' Y) which is supplied to this. The signal (E'v - E'Y) is supplied to the matrix forming circuit 97 via an amplifier 96 to 'reconstruct the color signal E' from E<1>.

The luminance information signal available at the output terminal 49 of the transmitter device is supplied directly to the input terminal 49' of a circuit 100 which is tuned to the frequency of the luminance signal carrier and whose output is coupled to a discriminator 101. The output of the discriminator 101 is coupled via an amplifier 102 to each of the inputs of the arrays 84, 97, 94 to reconstruct the signals E1 K , E' £5, E'v as previously discussed.

The operation of the discriminator circuits 81, 91 and 101 is synchronized at the beginning of each line by means of a clock signal coming from a clock oscillator 110 which receives control signals from the line and field time bases 120 and 130 to which the line and field synchronization signals respectively are applied separately of a separator circuit 40. The separator circuit's input terminal 56' is connected to the transmitter device's output terminal 56 on which the line and field synchronization signals sent by the transmitter device's main clock 34 are available.

If desired, the decoder's discriminators can be controlled by means of the high-frequency signals available on the transmitter device's terminal 55 and supplied to the input terminal 55', so that a demodulation is obtained from the said discriminators during a closer or reduced time interval, and therefore a higher accuracy.

The control of the picture tube guns is carried out on i and

manner known per se, in that the luminance signal is supplied to it

cathodes, the chrominance signals R, V, B are supplied to each of its grids G^, and between the cathode and the grid G-^ a resting bias is applied, erasing or erasing pulses emitted by the clock 110 with the line frequency and with the field frequency.

Separately adjustable voltages supplied by a block 150 are also applied to each of the grids G2. An adjustable concentration voltage is applied to the grid G^ supplied by a block 160 which is coupled to the block 140 and to the line time base 130. A very high regulated voltage THT supplied to the pipe and delivered by a regulator 180 and a rectifier circuit 170 which is connected to the regulator's input, the circuit's 170 input being connected to the line time base's 130 output. Deflection and vertical and horizontal dynamic convergence circuits 190 and 191 are coupled to the field and line time bases to form the appropriately shaped signals on the windings corresponding to the three (red, yellow, blue) picture tube guns.

As shown in fig. 5, the receiver device according to the invention also contains a circuit 200 for decoding the anti-copying signals which are introduced instead of at least part of the identification signal which is intended to control the phase of the inverter in the receiver device of the SECAM type. This circuit receives at its inputs 48'', 49'<1>bg 50'' the three video information signals available at the output terminals 48, 49 and 50 of the transmitting device. This decoding circuit allows the display of the meaning of the anticopy code on the picture tube: and for this purpose one of its outputs is connected to the input of three video amplifiers 301, 302 and 303 whose three outputs are connected respectively to the red, green and blue control electrodes of the picture tube. At the time of displaying the meaning of the anti-copying code, the decoding circuit also allows control of three analog switches 401-403 which are connected between the amplifiers 301-303 and the respective matrices 84, 97 and 94. These analog switches thus allow stopping the transmission of the color signals from the matrices' 84, 97 and 94 outputs.

Fig. 6 shows as an example the detailed circuit diagram of the decoding circuit. At its inputs, a bell circuit (bell circuit) 201 receives the video information signals containing the anticopy oscillation series, and the circuit is connected to a demultiplexer 202 whose outputs are connected to the inputs of a read storage 203 which converts the information representing the anticopy code into a digital signal, f .ex. in parallel on its inputs. As an example, the read storage 203 can emit the digital signal via four output lines if a presentation in sixteen colors of the meaning of the anti-copying code is desired.

The outputs from the read storage are connected to the respective inputs of three parallel-series shift registers 204,

205 and 206, as the outputs from these registers are connected to the picture tube canon's red, green and blue electrodes via amplifiers 301-303. The demultiplexer 202 is controlled by a gate device 207 with three inputs to which in fig. 3 shown signals b, c and d are applied. As already discussed earlier in connection with the transmitter device, these signals are produced in the SECAM-type encoder and represent respectively the double line sequence port, the whole image or partial image and line identification location unit, and the identification port. To determine the time of presence of the identification signal a, and therefore the presence of the anti-copying signals, it is sufficient to detect the change of state of the signal b which is supplied to the input terminal of the gate device 207 via an inverter.

The control of the decoding circuit 200 can be carried out, for example, by influencing a key on a keyboard to send a pulse to the "inhibition" input IN of the read storage 203, this pulse simultaneously controlling the opening of the analog switches 401-403 to prevent the picture tube from sending the color signals that appear on the matrix's outputs. The various elements that make up the decoding circuit can be controlled by a master clock 208 or, if desired, by the transmitter device's high frequency output signals.

It will therefore be realized from the foregoing that the user can at any time display the meaning of the anti-copying code by controlling the decoding circuit, and at the same time control the high resolution of the corresponding image. When the decoding circuit is made inactive, of course, the picture tube displays an image as defined by the color signals appearing at the outputs of the matrices 84, 97 and 94, such as those shown in fig. 4. It should be noted that the anticopy code information signals are also transmitted through the chrominance channels.

The receiver device in fig. 5 can be fed independently by means of a direct voltage supply device (not shown) which is identical to that used for feeding the transmitter device. It is obvious that the receiver device can be fed by the same direct voltage supply device as the transmitter device when the two devices are interconnected.

The aforementioned outputs and inputs on the transmitter and receiver devices can be connected via a cable which is provided at both ends with a connector of the multi-pin type.

It is also possible to construct the camera, transmitter and receiver system as an independent unit to allow a user to directly control the centering or framing of the image and its high resolution during recording or filming thereof.

Various modifications can be introduced in the receiver device without deviating from the scope of the invention. For example, the control of the start or stop of the decoding circuit, instead of being carried out manually, can be carried out automatically by means of a suitable circuit, such as a microprocessor or the like.

Claims (12)

1. System for processing color television signals, in particular of the SECAM type, comprising a device, such as a color television camera, for sending chrominance auxiliary carrier wave signals and. the luminance signal to a receiving device, such as a color television receiver, a control monitor or the like, the receiving device comprising a device for decoding the received information video signals, characterized in that the decoder device comprises first and second tuned circuits (80, 90) each of which receives a chrominance auxiliary carrier wave signal, the first tuned circuit (80) is connected to a discriminator (81) which produces the color difference signal (E1 - E' ), while the second tuned circuit (90) is connected to another discriminator (91) which produces the color difference signal (E' B - E ' X), and a third tuned circuit (100) which receives the luminance information signal E'y and is coupled to a discriminator (101) which provides the DC component of the luminance signal, as the output signals from the first, second and third discriminators are supplied to a matrix forming circuit (84, 97, 94) to produce the color signals E<*>/E1 and E' , as the three R V B discriminators at the beginning of each line are synchronized on the same clock signal. 2. System according to claim 1, characterized in that said clock signal is derived from a clock (110) which is connected to the outputs of the line and full-image or partial-image time bases (120 and 130) to which the line and full-image or partial-image respectively - the synchronization signals are supplied. 3. System according to claim 1, characterized in that the said clock signal is a high-frequency signal which is derived from the transmitter device's main clock (34). 4. System according to one of the preceding claims, characterized in that each of the line and full-frame or partial-frame synchronization signals is provided by a separation circuit (140) whose input terminal is connected to the output terminal from the transmitter device on which the line and full-frame or partial-frame synchronization signals are available. 5. System according to one of the preceding claims, characterized in that it comprises a circuit (200) for decoding the code that is inscribed in the anti-copying signals that are introduced in the sequences of information video signals supplied by the transmitting device, and that is connected to the picture tube in order to demonstrate the meaning of the anticopy signal code. 6. System according to claim 5, characterized in that the decoding circuit (200) contains a bell circuit (bell circuit) (201) which receives the information video signals, a device (202) for the reconstruction of the information relating to the anti-copying code introduced in the information sequence, and which is connected to a reading storage (203) which converts the signals supplied to it into digital form, and placement devices (204, 205, 206) which are connected to the reading storage and whose outputs are connected respectively to the picture tube's red, green and blue electrodes. 7. System according to claim 6, characterized in that the reconstruction device comprises a demultiplexer (202) which is controlled by a detecting device, such as a logic gate (207), with the period for the appearance of the anti-copying information. 8. System according to claim 6 or 7, characterized in that the placement device comprises three shift registers (204, 205, 206) whose outputs are connected to the respective, mentioned red, green and blue cannon via three video amplifiers (301, 302, 303). 9. System according to claim 8, characterized in that the shift registers are of the parallel-series type. 10. System according to one of the preceding claims, characterized in that the elements that make up the decoding circuit are controlled by a master clock (208). 11. System according to one of claims 6-10, characterized in that the decoding circuit is in directed to decode the anticopy signals partially inserted in place of the identification signals. 12. System according to one of claims 8-11, characterized in that it also comprises three analog switches (401, 402, 403) which are connected between the chrominance channel matrices (84, 97, 94) and the aforementioned video amplifiers (301, 302, 303) , the switches being controlled from the decoding circuit (200) to display either the meaning of the anti-copying code or the image represented by the color signals coming from the chrominance channels.