NO840837L - PROCEDURE AND SYSTEM FOR THE TREATMENT OF COLOR REMOTE SIGNALS OF THE SECAM TYPE, INCLUDING A DEVICE FOR UNLAWFUL COPYING - Google Patents

Description

The invention relates to a method for processing color television signals, particularly of the SECAM type, with a view to their transmission to a receiving device, such as a recording device, e.g. a magnetic tape cassette, and a system for carrying out the method.

It is known that registrations or recordings, e.g. on a magnetic tape, can easily be copied or duplicated. A person in possession of the recording, e.g. has it for rent, can make one or more copies of it without such copying being able to be controlled. He can also replace the magnetic tape containing the original recording with a copy of this without the owner of the original recording noticing the change.

The purpose of the present invention is to provide a solution to this problem.

For this purpose, the method according to the invention is characterized by the fact that anti-copying signals are introduced into the information part of the chrominance signals DR and Dfi and the luminance signal e'v which is to be transmitted to the recording device, which is not intended for display during a reproduction or playback.

According to an advantageous feature of the invention, at least part of the identification signal in the transmitted information which is intended to ensure the correct operation of the device for switching the chrominance signals DR, , of the SECAM type, in the recording device, is replaced with a signal with a frequency that lies outside the frequency passband provided in the recording device, so that a second recording made from the first recording results in a reproduction with poor quality.

According to another feature of the invention, the anti-copying signals constitute a code which allows identification of the first registration as the original registration.

According to yet another advantageous feature of the method according to the invention, in each chrominance signal and luminance signal sequence, a synchronizing pulse is provided consisting of a series or burst of oscillations with a frequency that lies outside the frequency passband for the corresponding signal paths in the receiver device, so that the synchronism of the synchronization signals and the luminance signals are no longer secured in a second recording which constitutes a copy of the first recording, and in the reproductions or playbacks made from such recordings of copies.

The system for carrying out the method according to the invention is characterized by the fact that it comprises a device for introducing anti-copying codes, such as a keyboard, a device which is designed to produce from the code a suitable series of oscillation bursts and a device for introducing the aforementioned burst instead of part of the information that is normally transmitted to the receiving device.

The invention will be better understood and other purposes, features, details and advantages of it will appear more clearly from the subsequent detailed description with reference to the schematic drawings which show an example of an embodiment of the invention, and where fig. 1 shows a block diagram of the treatment system according to the invention, fig. 2 shows in the form of a block diagram the principle of an anti-copying device according to the invention, fig. 3 schematically illustrates the identification signal for controlling the operation of the electronic switch in a SECAM receiver, and the signals used in the invention to determine the period during which the identification signal is present, and fig. 4 shows the location of the synchronization pulses which are constituted by anticopy oscillation pulse trains.

In the block diagram shown, 1 shows a receiver (or recording device) in a color television camera, and 2 shows the arrangement of the three matrices which are arranged at their outputs to produce the chrominance signals, i.e. the color difference signals DR = E'R - e'Y' db = E'b " E'y09 the luminance signal E'v of the SECAM type.

The processing system according to the invention comprises three voltage controlled oscillators 3, 4 and 5 which are suitably of the quartz crystal controlled type. Oscillators 3 and 5 are designed to produce the auxiliary carrier wave frequencies for the chrominance signals DR and Dg, while the oscillator 4 generates the luminance signal carrier. In accordance with the invention, the oscillators 3 and 5 are arranged to produce subcarriers whose frequencies are equal to multiples of the SECAM system's conventional auxiliary carriers of 4.406 and 4.25 MHz. The ratio between the auxiliary carriers generated by the oscillators 3 and 5 is identical to the ratio between the aforementioned conventional auxiliary carrier waves, in order to ensure the compatibility between the system according to the invention and the conventional systems. The auxiliary carrier waves are of course frequency modulated with the signals DR and DB.

As a result of the use of chrominance or color auxiliary carriers with a frequency that is a multiple 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 coded binary words, e.g. in accordance with the "N.R.Z." mode (the non-zero return mode) which is known per se and is used for example in the teletext system ANTIOPE. The subsequent processing to be applied to the frequency-modulated auxiliary carriers,

is further limited to frequency division operations, which only results in a single loss of information, but ensures a many-fold stability.

As can be seen from fig. 1 and 2, the processing system according to the invention comprises an anti-copying device 6 which essentially comprises a keyboard 61 which allows a predetermined pulse to be selected by the action of, for example, a key or several keys, a ROM or reading storage 62 whose function is to transform the information which is entered using the keyboard, to a digital signal that appears, for example, in parallel at the warehouse's outputs. These outputs are connected to a group of parallel inputs to a multiplexer 6 3 which receives the outputs on a second group of inputs

.'from a voltage divider 64. From a clock frequency which

is shown at 65, this voltage divider produces either the same frequency on all these outputs or different and specific frequencies on these outputs.

The multiplexer 6 3 provides at its output a sequence or series of oscillation bursts (English: oscillation bursts) with the same frequency or with different frequencies corresponding to the digital signal at the ROM storage 6 2 output. This series of oscillation bursts is supplied to a device 66 which is located in the path of the signals emitted from the camera 1, 2. The device 66 has the function of preventing the transmission of at least part of the identification signal which serves to control the phase of the electronic switch or switch in a conventional SECAM-type receiving device.

The device 66 and the multiplexer 6 3 are controlled by a gate device 6 8 with three inputs to which the fig. 3 shown signals b, c and d are applied.

These signals are produced in the SECAM-type encoder and respectively represent the port for the double line frequencies, the partial image and line identification location and the identification port. At a in fig. 3 schematically shows the identification signal for controlling the electronic switch and which is replaced at least partially by the anti-copy oscillation bursts. It will be appreciated that the period during which the identification signal a is present is defined by the fact that the signals c and d are in the "1" state and the signal at b is in the "0" state. When reversing the signal b, the period of presence of the identification signal a can therefore be determined with the help of an AND gate, as can be seen from 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 receiver of the conventional SECAM type. It is possible to record the signals produced by the camera 1/2 for the first time, for example on a magnetic tape. However, if one wanted to make a second recording or recording, i.e. a copy, from this first recording, the quality of the second recording would be insufficient and result in a poor quality reproduction because the correct operation of the SECAM switcher would no longer be secured during reproduction from the copy. As for the frequency of the anticopy oscillations, this can conveniently be the same as the frequency of the oscillations produced by the auxiliary carrier and carrier generating oscillators 3, 4 and 5 whose frequency is equal to a multiple of the frequency of the conventional SECAM auxiliary carriers.

It is obvious from the foregoing considerations that the introduction of an anti-copying code consisting of bursts of oscillation with a frequency outside the passband of conventional receivers, in the signal sequences provided by the camera or by any other source of color television signals, prevents any fraudulent or illegal registration activity. The presence of the anti-copy code signals in the original signal sequences, and thus on the original recording or recording medium, also makes it possible to determine that this recording is the original and not a copy.

It should also be noted that the anti-copying device according to the invention is designed to be connected to an external device. For this purpose, an input 6 9 is provided which is linked to a processing unit 70 which, if necessary, interacts with and is active together with the keyboard 61 and the ROM storage 62. It should also be noted that the anti-copying device also allows writing in the partial images of numbers which allow these to be identified.

According to fig. 2 contains the anti-copying device

6 a further device or circuit 71 which allows an anti-copying function to be performed. As shown in fig. 4, which shows an oscillogram for a line corresponding to the 75% amplitude bar pattern for the colors white, yellow blued to green, magenta, red, blue and black (from left to right), each signal occurs at A, B and C of a synchronization pulse 72 which falls below the lowest possible levels of each signal. Now the device 71 is arranged to provide the synchronization pulses 72 for a burst of oscillations with a frequency that lies outside the frequency passband of the conventional SECAM receiver devices. These oscillations can be the auxiliary carrier waves produced by the oscillators 3, 5 at a frequency which is a multiple of the conventional SECAM auxiliary carrier wave frequencies. The device 71 can be made up of any suitable circuit capable of e.g. to perform the function of an AND gate with two inputs arranged to receive a synchronization pulse and, at 73, oscillation bursts, respectively.

Due to the fact that the anti-copying oscillations lie outside the passband of the receiving device, will also

in the latter case, the copies produced from a first registration no longer allow a good quality reproduction due to the loss of synchronism that increases rapidly from one copy to the other.

The processing system shown further comprises three analog/digital converters 10, 11, 12, each of which is intended for processing one of the three signals Dn, DD and E1. Each converter is connected to the output of one of the television camera's three matrices, either by means of a device 7 or by means of anti-copying devices 6. After each converter 10-12 follows a respective switching circuit 17, 18 and 19, either directly or by intervention of an interference eliminating device 20, 21 or 22. As the digital signals in binary code produced by the corresponding analog/digital converter 10, 11 or 12 are present on each bus in accordance with a parallel constellation, it is for each of the data buses provided a parallel-to-series converter 24, 25 or 26 which serves to convert the parallel constellation into

a serial constellation of signals.

Each of the interference eliminating devices

20, 21 and 22 comprise a processing unit 27, such as a micro-computer or a microprocessor, two £AM stores 28, 29 for storing respectively the entire partial image that is being produced by the camera, and the previous partial image , as well as a read storage 30 which contains the routine for the processing unit. The latter can also be programmed to ensure the generation of a very stable DC supply voltage, by means of digital/analog converters 31 based on a previously defined binary digit. This DC voltage can serve as a reference voltage for the system for feeding the various elements in the treatment device according to the invention, and in particular for producing the feeding for the oscillators 3, 4 and 5 in a manner to be described in more detail later. This voltage is available at output terminal 32.

The disturbance-eliminating device can also be provided with per se known devices for correcting errors contained in the digital signals relating to several binary elements, e.g. by ensuring the presence of a predetermined number of binary states in each signal. The treatment device 2 7 ensures execution of this in and of itself known function. The processing unit can be arranged to produce a signal indicating the absence of errors in the digital signals.

As regards 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 prevent operation of the converters during the corresponding time intervals, i.e. will allow free passage through the converters of the sequence parts that are concerned with this code.

In order to ensure perfect synchronization of the operation of the various elements in the system according to the invention, this comprises a quartz crystal controlled oscillator 34 which forms a generator for high frequency signals, e.g. of the order of 100 MHz. This oscillator performs the function of a master clock. As can be seen from fig. 1, the line, field, and half-line sync 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 clock signal conductors for controlling these elements are shown at 36, 37 and 38 respectively. At 39, the main clock 34 provides the synchronization signals for the auxiliary carrier wave and carrier wave generating oscillators 3, 4, 5. The synchronism of these oscillators is thus ensured by the synchronization signals being derived from the same high frequency signal. It should be emphasized that all synchronization and reference signals are obtained by dividing the clock signal frequency, so that a perfect stability of the thus obtained signals and a perfect synchronization of the frequency and phase of the oscillators 3, 4 and 5, and of the signals, is ensured, i.e. .their leading edge, and therefore of all the operations performed by the processing system according to the invention. To ensure frequency stability of the clock oscillator 34, e.g. to prevent possible thermal drift, this oscillator is connected to a stabilizing loop (not shown) which also contains oscillators 3, 4 and 5.

The direct voltage supply device designated by the reference numeral 40 may be designed to produce extremely stable supply voltages for the auxiliary carrier and carrier oscillators 3, 4 and 5. These voltages are available at the supply device's three output terminals 41. As schematically shown in the figure, they are supply voltage generating devices for the oscillators advantageously 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 shown schematically at 43 and as of the aforementioned signal produces a signal of, for example, 1 MHz. The latter signal is supplied to a saturated amplifier 44 which operates in on-off mode and which at 4 5 is supplied with the very stable direct voltage produced at 32 by one of the disturbance eliminating devices 20, 21 or 22. A converter 46 transforms the amplifier output signal into a

DC voltage available at the output terminals 41.

This voltage is completely stable as a result of the fact that it is derived from the clock frequency by means of frequency division, which already ensures a high degree of stability, and from the very stable voltage produced by the interference-eliminating devices from a binary digit. The amplitude of the output voltage is thus strictly controllable. It should also be noted that the supply device 40 is galvanically isolated from the mains voltage by means of a transformer (not shown).

As can be seen from fig. 1, the processing system according to the invention comprises output terminals 48-50 for the output signals from the oscillators 3, 4 and 5, i.e. for the auxiliary carrier waves which are modulated by the chrominance signals, and for the carrier wave which is modulated with the luminance signal. Output terminals 51, 52 and 53 are provided from which chrominance and luminance signals as produced by the color television camera can be extracted. The system also comprises output terminals 55, 56 from which the high-frequency clock signal produced by the oscillator 34, and the line, partial image and half-line synchronization signals can be extracted. Reference numerals 58 - 60 denote the output terminals of the data buses 17 - 19, while the serial configuration digital signals are available on terminals 61 - 63. The no-error signal is present on the output 64. Terminals 65 and 66 are connected to the supply device 40 and denote ground - and the supply potential.

All of the aforementioned outputs, or at least a substantial part of them, can be connected to a connector of the multi-pin plug type which can be connected to a receiving device, such as a video tape recorder, an ordinary color television set, a monitor for visual control and similar. By the fact that the system is also provided on its input side with a connector of, for example, the multi-pin type, it can form an independent unit that can be installed between a color television camera and a suitable receiver device. However, it is also possible to insert this system together with the camera and the receiving device, such as a color television receiver or a video tape recorder, in the same box or casing to constitute a kind of telecine apparatus or an apparatus for duplicating films or arbitrary documents.

The operation of the system according to the invention is immediately apparent from the preceding description of fig. 1. It therefore does not need to be described, apart from the operation of the interference-eliminating devices. Each of these devices works in the following way.

In order to eliminate interference or disturbance, the processing unit 27, which is controlled by the routines stored in the read storage 30, compares each partial image with the previous partial image. These partial images are stored in respective RAM stores 28, 29. As a result of this comparison operation, all the image elements common to both partial images will be retained. On the other hand, the non-identical elements will be eliminated. It should be noted that the two partial images are shifted in time from each other by 20 ms. The elements that represent the disturbance will therefore usually no longer be the same in both partial images. With the aid of suitable and relatively simple programming, the processing unit can be adapted to distinguish a difference in the two partial images, which is 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 the object essentially retain their shapes. They have only changed places in the two partial images. This non-change of the general shape of the image elements, which represents a moving object from one sub-image to the subsequent sub-image, allows the discrimination of disturbance which is of a random nature and is therefore in principle always different from one sub-image to the next. It is easily realized that the interference-eliminating device can be made even more advanced and sensitive to special parameters by connecting it to a suitably programmed, external computer.

The system according to the invention, as shown in fig. 1 and described above, can of course be modified in various ways without going outside the scope of the invention. For example, 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. The chrominance signals can be supplied to the auxiliary carrier generating oscillators 3 and 5, not in their analog form, but in their digital form obtained at the outputs of the analog/digital converters 10 - 12, and, if appropriate, after being have been processed by the interference elimination devices. This would allow obtaining output signals that are free from random noise. It must again be emphasized that the choice of the auxiliary carrier frequencies must be made in such a way that all the desired information and all the desired signals can be transmitted and processed so that a high sharpness is offered, and can be maintained in its original state without practically undergoing any deterioration. The system will be able to allow transmission of digital signals in any suitable code, e.g. signals of "N.R.Z."

(non-zero return) type, such as the signals used in the ANTIOPE system.

Claims (13)

Method for processing color television signals, in particular of the SECAM type, with a view to their transmission to a receiving device, in particular a recording device, such as a magnetic tape or the like, characterized in that anti-copying signals are introduced into the information part of the chrominance signals DR , Dg and the luminance signal Ev which must is transferred to the recording device, which is not intended for display during a reproduction. 2. Method according to claim 1, characterized in that at least part of the identification signal in the transmitted information which is intended to ensure correct operation of the switching device for the chrominance signals DR, Dfi of the SECAM type in the recording device, is replaced by a signal with a frequency that lies outside the frequency passband provided in the recording device, so that a second recording made from the first recording results in a reproduction with poor quality. 3. Method according to claim 1 or 2, characterized in that the anti-copying signals constitute a code which allows the first registration to be identified as the original registration. 4. Method according to one of the preceding claims, characterized in that in each sequence of the chrominance signals and of the luminance signal, a synchronization pulse consisting of a burst of oscillations with a frequency that lies outside the frequency passband for the corresponding signal paths in the receiver device is provided, so that the synchronism of the synchronization signals and the luminance signal is no longer secured in a second registration which constitutes a copy of a first registration, and in the renderings provided from such copy registrations. 5. System for carrying out the method according to one of claims 1-4, characterized in that it comprises an anti-copying device (6) which is arranged to introduce anti-copying signals in the information part to be transferred to the recording device, which is not intended for display during a reproduction . 6. System according to claim 5, characterized in that the anti-copying device (6) comprises an input device (61) and a ROM storage (62), a device (63, 64) which is arranged to generate a series of bursts of oscillations from the code, and a coincidence device, such as a logic circuit (71) for introducing the anticopy oscillation bursts into the information sequence. 7. System according to claim 6, characterized in that the device which generates the oscillation bursts comprises a multiplexer (63) with a group of inputs which are connected to the outputs of the ROM storage (62), and a frequency divider (63) whose outputs are connected to a second group of inputs to the multiplexer, the frequency divider on all its outputs producing either the same frequency or different frequencies. 8. System according to claim 5, characterized in that the anti-copying device (6) can be connected to a signal source for the external code. 9. System according to one of claims 5-8, characterized in that the anti-copying device (6) is arranged to allow the introduction of a code or the introduction of a code for identification of the sub-image in at least one partial image. 10. System according to one of claims 5-9, characterized in that the anti-copying code can be a code for checking the registration of an original and not of a copy. 11. System according to one of claims 1-10, characterized in that it comprises a device for at the beginning of the chrominance and luminance signals for each line to produce a synchronization pulse with a level that is lower than the minimum level of the chrominance and luminance signals, and that the anti-copying device ( 6) comprises a device for replacing the synchronization pulses with an anti-copy oscillation burst. 12. System according to one of the claims 5-11, characterized in that it comprises analogue/digital converters (10 - 12) which are connected after the anti-copying device (6) and are optionally supplemented with devices (20 - 22) for the elimination of disturbances and errors. 13. System according to one of the preceding claims, characterized in that it comprises oscillators (3, 4, 5) for the generation of chrominance and luminance auxiliary carrier waves whose frequencies are multiples of the conventional SECAM auxiliary carrier waves, and in that the anti-copy oscillations suitably have the same frequency as these auxiliary carriers.