LU86240A1 - METHODS AND DEVICES FOR ANALYZING AND RECOGNIZING THE CODE OF ENCRYPTION OF TELEVISION BROADCASTS - Google Patents

Description

The present invention relates to the field of so-called encrypted television and more specifically relates to the search for the encryption code, used in the context of the encryption of television image by application of delays between the image signal of each video line and the line synchronization pulse, these delays being variable and established from one line to another according to a pseudo-random code. Such encryption destroys the vertical structure of the image, making it unintelligible, the lines being offset with respect to each other and, for the same line, from one frame to another of the same parity in the same cycle. Only compensation for these delays in reception makes it possible to restore the synchronization of the different image signals from one line to another, the compensation code itself being a function of the pseudo-random code of delays used during encryption.

Such encryption and decryption devices currently exist in Europe in the context of prepaid televisions, intended to be decoded only by a certain category of subscribers (cf. French patent 75.34029 and French patent applications 82.05006 and 82.05007).

The object of the invention is to arrive at determining the pseudo-random cycle of the offsets used during coding, so as to restore it to a suitable decoder which will then be capable of providing a correct image from the encrypted version of the 'itaage, this without it being necessary for the encryption organization to communicate to each subscriber the new encryption code used at each change thereof.

However, for this invention to be usable, the pseudo-random code of the successive shifts between the line video image signal and the synchronization pulse of this same line, from one line to the other, that is to say a cyclic code, that is to say established for 2 a finite number T of frames and reset at the end of these T frames thanks to an indication of cycle synchronization carried by the video transmission, the audio transmission or both together (for example, the cycle can be reset every 6 frames thanks to a uniform white level carried by the last line of the end of cycle frame, this last line of frame remaining black, in the other 5 frames cycle, as suggested in French patent application No. 82 05008).

In addition, the number of possible different shifts must be a finite number? call it d (for example d = 3, i.e. 3 different types of shifts Tl, T2, T3 with, for example, T1 = 0, T2 = s, T3 = 2s and with s = lps) .

These two conditions are effectively fulfilled in the context of current European applications of this encryption mode.

The invention in question can then take two different forms: a form known as for visual analysis which processes the signals so as to allow the human eye to determine for each of the lines of the cycle of T frames the value of the offset, a device then making it possible to store for each of these lines the value of the offset observed. The total memory of all these offset values classified frame by frame and by successive lines then represent the pseudo-random code sought? - a form called automatic analysis which makes it possible to replace the human eye with an electronic circuit capable of judging, either by a comparative process, of the presence or not of an offset between 2 successive lines of the same frame, or by a method of analysis over a given range of a suppression level.

According to the first of the two forms above, the method according to the invention is defined by claim 1 and the device for implementing it by claim 10. According to the second of the two forms above, a ψ 3 first method automatic according to the invention is defined by claim 6, a second method by claim 9 * and the devices for implementing them by claims 14 and 17 respectively.

We will call, within the framework of this patent and in accordance with the technical specificities currently in force, "level of suppression" the part of the video line starting at the end of the rising edge of the line synchronization top and ending at the beginning of the that same video line supposed to be unencrypted or correctly decrypted.

Such a deletion stage therefore contains no image information and is used for the reference of black. When it is a question of "suppression level" for an encrypted video line, we will refer to a part of this video line starting at the end of the rising edge of the line synchronization top and of duration identical to the suppression level of an unencrypted or correctly decrypted video line.

The second method of analysis and automatic recognition of the encryption code of television broadcasts then consists in testing successively each of the different possible encryption codes on the encrypted video image using a suitable decoder and, for a given code, to be searched for over a determined number of frames, using an analysis device relating to certain of the lines thus obtained, the presence of an image signal over a determined analysis range of the level of suppression of these lines, a such signal being significant on the line considered of the application of a bad decryption by the adapted decoder.

Thus the presence of such an image signal on the determined analysis range of the suppression level for only one of the lines examined and for the code considered makes it possible to reject this code as being false and to pass to the analysis of the code. following.

* 4

Such a method can in particular be used when the number of different possible pseudo-random codes is small, and there are significant differences between each of these different codes, which is particularly achieved when these codes are themselves derived from '' a pseudo-random generator capable of generating the sequence of the encryption code for a complete cycle from a relatively short starting key. (Such pseudo-random code generators are currently used in Europe in the context of television programs encrypted by institution of delays, variable from one line to another, between the image signal of the video line and the line synchronization pulse.)

Such pseudo-random generators use different logical processes which it suffices to recreate, the analysis then no longer requiring that to successively test each of the different possible starting keys (for example, if the starting key is expressed in the form of an 11-bit word, there are 2 ^, that is to say 2048 different possible keys which it suffices to test one by one. If each of the tests requires 1 analysis frame, it will take a maximum of 41 seconds to find the correct key and therefore know the encryption code used, which is relatively short).

To better understand the invention, embodiments of the invention will be described in detail with reference to the figures in which FIG. 1 represents a device for analyzing and recognizing the encryption code implementing the method for visual analysis, FIG. 2 represents a signal making it possible to generate an index on a line, FIG. 3 represents a device for analysis and automatic recognition of the encryption code implementing a first method of automatic analysis, FIG. 4 represents the result of a subtraction of the signals of two neighboring lines of a correct or decrypted frame and of two neighboring lines encrypted or * * 5 badly decrypted, according to the first method of automatic analysis, FIG. 5 represents a device d analysis and automatic recognition of the encryption code implementing a second automatic analysis method and FIG. 6 represents different video lines within the framework of the second method automatic.

The method for the visual analysis consists in successively analyzing each of the T frames of the cycle of the pseudo-random code and, for each of these frames, successively each of the lines constituting it, so as to identify for each of these lines the offset which exists and save it on a memory at a location corresponding to it in the cycle. Once this analysis operation has been carried out for all the lines of the T frames of the cycle, the totality of the offset values recorded, and classified in order of frame and line, represents the encryption code sought.

FIG. 1 represents a very schematic view of a device according to the invention, implementing a method according to the invention.

This device comprises: a) A synchronization extractor 1 which makes it possible to extract the line synchronization pulses in 2 and the frame in 3 from the encrypted video image 100.

b) A coding cycle synchronization extractor 4 itself a function of the type of cycle synchronization video information provided by the encrypting body (in the example described, video information carried by the last line of the last frame cycle) and capable of providing cycle synchronization pulses.

c) A video switch (analog gate) 5 which allows the screen 200 to display only that of the T frames of the cycle being analyzed, thereby erasing the lines of the Tl other frames of the cycle and replacing them with a uniform gray level thanks to the device provided in 7. Such a 6 video switch also makes it possible to eliminate the shifts observed on the same line from one frame to another of the same parity, of the same cycle and, each of the lines displayed on the screen thus remaining at a fixed offset, allows the human eye a precise analysis of the absolute offset of each of the lines of the selected frame. The uniform gray meanwhile makes it possible to avoid too sudden a variation in luminance between two screens selected on the screen, by loss of the intermediate Tl frames, which would risk tiring the eye excessively taking into account the phenomenon of periodic flickering every T resulting frames. The video switch thus proposed is directly controlled by a frame selection circuit 9.

d) A frame selection circuit 9 which, on the one hand, allows, thanks to the synchronization pulses 2 and 3, to switch the video switch 5 at the start of each video line and of each frame, so as to let the line or frame synchronization information which, on the other hand, allows, thanks to the frame information of the .. cycle to be selected, coming from the counter circuit 50, on the one hand to switch the video switch 5 to the entire length of the selected frame and, on the other hand, to supply to the line selection circuit 11 the line synchronization pulses of the lines of this frame.

e) A circuit for marking the line being analyzed by display on the screen in sqperposition on a part of this line with a white rectangular index. Such a circuit consists of an index generator 15, directed by an index pointer 13, which is none other than a double monostable responsible, according to FIG. 2, for positioning the index at tl and for a duration t2, on the line being analyzed.

This index pointer is itself controlled by a line selection circuit 11.

f) A line selection circuit 11, which makes it possible to trigger the index pointer 13, and through it the index generator 15, at the time of the passage of the video information corresponding to the line of the cycle in progress d 'analysis. Such a line selection circuit * · takes account of the formation of the raster line to be selected coming from the counter circuit 50 and receives from the raster selection circuit 9 the line synchronization pulses of the lines of the selected raster.

g) A set of validation switches 20 allowing the manual selection of the offset values observed for each of the lines analyzed, it being understood that there are as many switches, or combinations of switches, as different possible offsets . The information is then directly transmitted to the memory 66 where it is stored at an address corresponding to the line of the cycle frame to which it refers, and allows the analysis of the next line of the cycle by incrementing the counter circuit 50 A particular switch 21 makes it possible to launch the analysis, the memory 66 being ready to keep the selected offset in the place corresponding to the 1st line of the 1st frame of the cycle by resetting the counter, all the information previously stored being either simply erased, or moved to another memory register * before erasing the working register. Finally, it is also possible to provide 2 additional advance and return switches intended to modify, by advancing or returning the counter circuit, the line of the cycle to be analyzed.

h) A memory 66 and a counter circuit 50 managing this memory, making it possible, as the line by line analysis is carried out, to store the value of the offset observed and optionally to restore a decoder adapted to each of the offset values previously stored , at the time of the video passage of the line of the cycle corresponding to it. The counter circuit also makes it possible to inform the frame selection circuit 9 and the line selection circuit 11 of the frame or of the line of the cycle being analyzed. This counter circuit receives the frame synchronization pulses 3, line 2 and cycle pulses from * - 4, as well as the increment pulses, from 20, each time a new value is validated by the selector.

8

A method using the device described therefore makes it possible, at the end of the analysis, to obtain knowledge of the pseudo-random cycle of encryption used on transmission.

t.

y Of course, such a method is only of interest if the pseudo-random code used remains fixed for a fairly long period of time (for example of the order of a month), taking into account the relatively long time it takes. devote to the process to obtain the pseudo-random code sought (for example if t = 6 frames and it takes 1 second to analyze each line, it will take approximately 31 minutes of work before obtaining the entire code) .

Such a method can finally be coupled in real time with a suitable decoder 30, so as to show on the screen, as and when a frame is analyzed, the part already analyzed in decrypted form. To do this, a circuit 40 recognizes the commissioning of the adapted decoder 30 and makes it possible to toggle the switch 41 so as to replace the encrypted video information 100 by the video information coming from the adapted decoder, this latter retaining the offset of the lines of the cycle not yet analyzed, the memory restoring for these lines a maximum offset value, resulting from the resetting to memory, and corresponding to a zero compensation delay for the adapted decoder. invention and a suitable decoder, coupled, which can be considered as a "video game" which would consist in making the decoded image appear as quickly as possible.

A simplified version of these method and device for analyzing and recognizing the encryption code for visual analysis can also be implemented when, on the one hand, the number of different possible pseudo-random codes is a finite number (let's call the N) and that, on the other hand, any 2 codes taken from the N different possible pseudo-random codes have, in a determined position of the cycle, never more than n successive offset values, common for these 2 codes.

9

It then suffices to limit the visual analysis described according to the invention to n successive lines of the cycle taken in this determined position of the cycle, plus a line adjacent to these ~ n lines - either to the first or to the last of the n lines. -, the counter circuit 50 making it possible in this simplified version to limit the visual analysis to these n + 1 lines of the cycle and to command the recognition circuit 55 comprising a microprocessor, at the end of this analysis, to determine according to the n + 1 values stored in the memory 66 which of the N different possible pseudo-random codes was used for encryption, by comparison of these n + 1 offset values resulting from the analysis with successively, each of the N series of n + 1 offset values it has in memory and corresponding to each of the N different pseudo-random codes possible at this position of the cycle. Once this code has been identified, the recognition circuit provides information specific to this code to the pseudo-random code generator 61 which itself will restore the offset values according to this code to the suitable decoder 30, each at the time of passing through the television video transmission of the line of the corresponding cycle, this thanks to the synchronization pulses of lines, frame and cycle which it receives. The adapted decoder 30 then makes it possible, by virtue of these offset values, to decrypt the television program coming from 100 properly and to supply the decrypted version directly to the television 200.

To be effective, the automatic analysis process requires that the number of different possible pseudo-random codes is not infinite. ·

In this case, the method consists in successively testing each of the different possible codes using a suitable decoder (cf. French patent application 83 05 006) and, for a given code, checking on a determined number of frames, thanks to a line-to-line analysis device described in the invention, the presence or absence of offsets on the video image obtained.

If a significant number of shifts are observed, the code will be rejected and another code will be analyzed; otherwise, the code would be retained as the correct one.

Such a method can be used in particular when the number of different possible pseudo-random codes is small, and there are significant differences between each of these different codes, which is particularly achieved when these codes are themselves derived from a pseudo-random generator capable of generating the sequence of the encryption code for a complete cycle from a relatively short starting key. (Such generators of pseudo-random codes are currently used in Europe in the context of television programs encrypted by institution of delays, variable from one line to another, between the image signal of the video line and the ~ line synchronization pulse.)

Such pseudo-random generators use different logical processes which it suffices to recreate, the analysis then no longer requiring that to successively test each of the different possible starting keys (for example, if the starting key is expressed in the form of an 11-bit word, there are 211, that is to say 2048 different possible keys which it suffices to test one by one. If each of the tests requires 1 analysis frame, it will take a maximum of 41 seconds to locate the correct key and therefore know the encryption code used, which is relatively short).

FIG. 3 represents a very schematic view of a device according to the invention, implementing the automatic analysis method.

Such a device comprises: a) a synchronization extractor 1 making it possible to obtain from the video image 100 the line synchronization pulses in 2 and the frame in 3.

b) A coding cycle synchronization extractor 4, itself a function of the type of cycle synchronization video information provided by the encrypting body (in the example described, video information carried by the last line of the last cycle frame) and capable of supplying cycle synchronization pulses.

c) A code generator 60 capable of creating or restoring all of the different possible pseudo-random codes. Such a generator receives the synchronization pulses of line 2, of frame 3 and the synchronization pulses, of cycle from 4.

d) A suitable decoder 30 capable of reproducing, in the presence of the correct encryption code of the video image from the generator 60, a perfectly decrypted video image. During the analysis period, this suitable decoder 30 receives the codes to be tested from the generator 60 and transmits to the analyzer 300 the transformed video image according to the decryption code as a function of the encryption code analyzed.

e) A switch 70 making it possible to reset the code generator and therefore to restart the entire analysis.

f) An image analyzer 300 characterized in that it comprises: - A rejection filter of the color subcarrier 10.

It is a "plug" circuit at 4.286 MHz for SECAM; 4.43 MHz for PAL; 3.58 MHz for NTSC. Such a filter makes it possible to filter the chrominance so as to retain only the luminance.

- A delay line with delay value a line period (64 days for PAL or SECAM, 63.5 days for NTSC) can be. either a charge transfer line controlled by a clock generator,. or an acoustic delay line equipped with its modulator and demodulator.

Such a delay line is responsible for delaying each video line so as to compare it with the next video line of the same frame. The delayed video line therefore goes to el and the next non-delayed video line with which it is compared to e2.

12 - A subtractor 16 responsible for subtracting these 2 successive video lines from the same frame passing respectively into el and e2 in order to keep only the difference that is analyzed.

As shown in Figure 4, the result of this j subtraction is close to zero when there is no shift and the information carried by these 2 lines is almost identical (case on the left), whereas on the contrary, if there is a time offset t between these 2 lines (right case), the subtraction will give for each of the vertical details carried by these lines portions of positive and negative lines of duration tQ, on the resultant of this subtraction.

- A window generator 18 taking account of the synchronization 2 and frame 3 pulses, responsible for triggering window switches 14, 14 ′ so as to keep the incoming video signal only a certain number of lines for each frame and only 'a central part for each of these lines. ^ ^ The first window switch 14 triggered by the window generator 18 is responsible for keeping only a certain number of lines for each frame and only a central part of the information video from subtractor 16, as shown in Figure 4 according to examples A and B, for these lines.

- (d-1) frequency selective analysis channels, placed in parallel, each one being specific to one of the (d-1) different possible offset times (the zero offset is not taken into account).

Each of these (d-1) channels consists of:. a bandpass filter 22 adapted to one of the (d-1) possible offset times and responsible for keeping the input signal only the part specifically linked to this offset time, - a detector alternating circuit 23 responsible for detecting the presence of the signal, - a threshold level detector with integrator 24 capable of integrating the level offset information above this threshold, and of informing the decision logic circuit 45 to each achievement of the integration level.

13 - the second window switch 14 ′, triggered by the same window generator 18 and making it impossible to; consider that a certain number of lines for each frame and that a central part of the video information of each of these "lines, - of a threshold detector 51 making it possible to keep only the part of the video signal taken into account located above this threshold, - a bandpass filter 52 allowing only fine details (rapid transition) of the image to pass through, - a counter 53 enabling the logic circuit to be informed decision 45 of the analytical value of the line considered until a minimum number of fine details is obtained This counter is automatically reset to zero on each new line thanks to the line synchronization pulse 2.

- A decision logic circuit 45 which takes into account, for a determined number of frames analyzed, the number of lines judged analytically suitable by the transition counter and the number of shifts counted by the (d-1) selective analysis channels on all of these lines to inform, in the form of a 2-bit word, the code generator 60 * of the result of the analysis on these frames.

The code recognition information as being the correct one is transmitted in the form: 01; the information recognizing the code as being false is transmitted in the form: 10; finally the reanalysis information of this same code in the form: 00.

Such a device ultimately allows and after a variable analysis time, depending on the number of codes to be analyzed before finding the right one and the analytical quality of the images taken into account (a minimum of fine details being necessary), recognize the correct encryption code and therefore give it to a decoder suitable for decrypting television programs thus encrypted.

Such a method is therefore only valid from the moment when the time for automatically searching for the encryption code is short compared with the time during which this code is applied (for example for an encryption code valid for one month and one analysis on the order of 30 minutes). However, in the event that the encryption code is rapidly changed but still chosen within a limited number n of different codes (for example n = 8) set for * a relatively long period of time (for example order of the month), and if specific information, specific to that of the n codes used at a given time, is conveyed by the video information, or the audio information, or both at the same time before or at each code change , it remains possible to proceed according to the invention, provided that account is taken, for each analyzed frame, of the code among the n possible ones, in use, and to continue the analysis according to n sub-levels of analyzes of which it would be it is possible to switch from one to the other whatever while keeping in memory the analysis operations already carried out on each of these sub-levels, and this until obtaining the value of the n codes. It will then suffice to restore them each, as a function of the information specifying that of the n codes used, during the time of use - respective, to an appropriate decoder, to obtain a perfectly decrypted image of the initial encrypted version.

15

Let us now see the second method of analysis and automatic recognition.

FIG. 6 represents, from the point of view of luminance, in the context of an example of encryption with 3 offset times (0, T, 2T), and for a schematic image signal whose start is immediately a level medium of white, all the different video lines obtainable using the appropriate decoder applied to the encrypted video image, in the presence of the correct encryption code (E), or of a bad encryption code (G ) compared to all the different video lines' that can be obtained with encryption (F). Example (E) also represents the video lines as they are received in the absence of encryption, still from the point of view of luminance. H represents the suppression level and P a range of the suppression level on which the analysis can be carried out, any analysis range chosen on the suppression level having to contain at least part of this range P to be operational.

FIG. 5 represents a device for automatic analysis and recognition of the encryption code implementing the second method of automatic analysis by study of one; blanking range.

Such a device comprises: a) a synchronization extractor 1 making it possible to obtain from the video image 100 the line synchronization pulses in 2 and the frame in 3.

b) A coding cycle synchronization extractor 4, itself a function of the type of cycle synchronization video information provided by the encryption organization (in the example described, video information carried by the last line of the last cycle frame), and capable of providing cycle synchronization pulses.

c) A code generator 60 capable of creating or restoring all of the different possible pseudo-random codes. Such a generator receives the line 2, frame 3 synchronization pulses and the cycle synchronization pulses from 4.

d) A suitable decoder 30 capable of reproducing, in the presence of the correct code for encrypting the video image originating from the aerator 60. a video imaoe that is perfectly decoded.

16

During the analysis period, this suitable decoder 30 receives the codes to be tested from the generator 60 and transmits to the analyzer 300 ’the video image transformed according to the decryption code depending on the encryption code analyzed. The adapted decoder receives; line synchronization pulses 2 from synchronization extractor 1.

e) A switch 70 making it possible to reset the code generator and therefore to restart the entire analysis, and a video screen 200 making it possible to view the image according to the decoding carried out.

f) An image analyzer 300 'characterized in that it comprises: - A rejector filter of the color subcarrier 10.

It is a "plug" circuit at 4.286 MHz for SECAM; 4.43 MHz for PAL; 3.58 MHz for NTSC. Such a filter makes it possible to filter the chrominance so as to retain only the luminance.

- A black alignment circuit 26 making it possible to restore the DC component of the signal.

- A comparator circuit 27 which delivers a logic level 1 when the level of the video signal is greater than a chosen reference level R.

- A window generator 18 making it possible to take into account in the analysis only certain lines for each frame and, for these lines, only a certain range of the suppression level. This window generator delivers a logic level 1 within the times taken into account in the analysis.

- An "AND" logic gate 28 which processes the information coming from the window generator on the one hand, and from the comparator circuit on the other hand.

- A decision circuit 29 which, as a function of the number of pulses received per frame, informs the code generator 60, in the form of a 2-bit word, of the result of the analysis on this frame. The code recognition information as being the correct one is transmitted in the form: 01; the information recognizing the code as being false in the form: 10; finally, the reanalysis information of this same code in the form: 00, as long as a sufficient number of frames has not been taken into account in the analysis of the code.

17

Such a device ultimately allows and after a variable analysis time, depending on the number of codes to be analyzed before finding the right one and the analytical quality of the lines taken into account (minimum luminance at the very beginning of the signal image is necessary), to recognize the correct encryption code and therefore to give it to a decoder suitable for decrypting the television programs thus encrypted.

Such a method is therefore only valid from the moment when the time for automatic search of the encryption code is short compared to the time during which this code is applied (for example for an encryption code valid for one month and an analysis about 30 minutes). However, in the event that the encryption code is rapidly changed but still chosen within a limited number n of different codes (for example n = B) fixed for a relatively long period of time (for example of the order of months), and if particular information, specific to that of the n codes used at a given time, is conveyed by video information, or information - audio, or both at the same time before or at each code change, it is still possible to proceed according to the invention, provided that account is taken of the code among the n possible, in use, for each analyzed frame, and to continue the analysis according to n sub-levels of analyzes which it would be possible switch from one to the other whatever while keeping in memory the analysis operations already carried out on each of these sub-levels, and this until obtaining the value of the n codes. It will then suffice to restore them each, according to the information specifying that of the n codes used, during the respective time of use, to an appropriate decoder, to obtain a perfectly decrypted image of the initial encrypted version.

The methods and devices according to the invention can also be used for searching for the encryption code when the television broadcasts are not only encrypted, as indicated in the preamble to claims 1, 6 and 9, but also apply. a method for reversing the polarity of the video signal (as described in French patent application 75 34029), operated on one or more determined lines of the cycle and for each cycle on the same lines. Such polarity reversals can be recognized either by the operator performing the visual analysis or by a simple circuit; the signal can then be restored corrected for this reversal of polarity, which makes it possible to apply the methods and devices of the present invention. The information indicating that such a line of the cycle has undergone a reverse polarity can easily be stored in a memory supplementing that retaining the offset values, and the information be restored to the suitable decoder so as to correct this reverse polarity in conjunction with the compensation for the shifts it operates.

It should also be noted that, without departing from the scope of the invention, it remains possible to proceed according to the invention with less than d -1 channels of frequency selective analysis as soon as it is certain to detect with the channels analyzes taken into account and for all the different possible codes, except the correct one, a minimum number of shifts per group of frames analyzed.

’-X

Claims (17)

19 1. Method for analyzing and recognizing the encryption code of television programs for visual analysis, the encryption being obtained by imposing a delay, variable from one line to another, between the image signal of the video line and the line synchronization pulse, these »delays being established from one line to another according to a pseudo-random code reset cyclically every T frames, characterized by a consistent encrypted signal processing, for each cycle, to display on a screen only a first frame of the T frames of the cycle by erasing the Tl other frames of the cycle, this operation being repeated for the time necessary for the analysis of all the lines constituting this frame of the cycle , to keep in memory a delay value introduced to a selector by an operator according to its estimate of the offset of the first line analyzed, then to keep in memory in a second place the value selected by the operator for the second l igne and so on for all the lines of the first frame, then of the second frame and so on until the last frame of the cycle, the delay values being classified in memory in order of frame then of cycle line, thus constituting the pseudo-random encryption code sought. 2. Method according to claim 1, characterized. in that it makes it possible to mark on the screen the line being analyzed, by superimposing on a part of this line a white index. 3. Method according to claim 1 or 2, characterized in that it makes it possible to replace, during the analysis of one of the T frames of the cycle, the Tl other frames of the cycle which are erased by as many frames composed of lines all identical and corresponding to a uniform gray level, so as to moderate the flickering phenomenon every T frames which results from this erasure. ~ 4. Method according to one of claims 1 to 3, characterized in that the selected delay values are directly applied by a decoder adapted to compensate for each cycle of the line shifts to which they relate. 5. Method according to claim 1, characterized in that, when the pseudo-random code used is taken from a finite number of different possible pseudo-random encryption codes and that there are, between any two of these different possible codes , never more than n successive offset values, common for these two codes,. in a determined position of the cycle, it suffices to limit the visual analysis to these n successive lines of the cycle plus a line, adjacent to the first or to the last of these n successive lines of the cycle, a recognition circuit (55) then making it possible to determine, thanks to the n + 1 successive offset values stored at the end of the analysis, that of the various pseudo-random encryption codes used . 6. Method for analyzing and recognizing the encryption code of television programs according to an automatic analysis method, the encryption being obtained by imposing a delay, variable from one line to another, between the signal image of the video line and the line synchronization pulse, these delays being established from one line to another according to a pseudo-random code reset cyclically every T frames, characterized in that a first pseudo code - random encryption possible is generated by an adequate circuit, that a decoder applies the additional delay values, corresponding to this first code, to the decryption of the lines of at least one corresponding frame of the cycle, than an analysis circuit check on each of the frames thus obtained the presence of offsets between the successive lines, taken two by two, of this frame by delaying the signal of each line by the value of a line period and by subtracting it from that of the following line ,'for identify on the difference the presence of significant offset signals, that when a minimum number of line shifts is noted after - the analysis of these frames, a second encryption code is generated and the analysis operation is repeated, then a third encryption code, etc. until the generated encryption code 21 produces, thanks to this decoder, frames for the whole of which less than a determined number of shifts is perceived between the successive lines of each of them, which causes the end of analysis and storage of the last code used. 7. Method according to claim 6, characterized in that the result of the analysis of the last code retained is judged valid only if the video information carried by the frames having allowed the analysis of this code are judged favorable, this by the presence of a minimum of "fine details" in the image allowing the analysis circuit to work efficiently. 8. Method according to claim 6 or 7, characterized in that when the encryption applies a delay taken from d-1 different possible times and a zero delay, the analysis circuit operates with at most d-1 selective analysis channels in frequency, placed in parallel, each one being specific to one of the d-1 different possible offset times: Bibles. 9. Method for automatic analysis and recognition of the encryption code of television programs, the encryption being obtained by imposing a delay, variable from one line to another, between the image signal of the video line and the line synchronization pulse, these delays being established from one line to another according to a pseudo-random code · cyclically reset all the T frames, characterized in that a first possible pseudo-random encryption code is generated by an adequate circuit, that a decoder applies the complementary delay values, corresponding to this first code, to the decryption of the corresponding lines of the cycle, that an analysis circuit searches on some of the lines thus obtained for the presence of a signal image on a given range of the suppression level, in that when in a minimum of these lines for a group of frames considered, an image signal is perceived on the given range of the suppression level, a second encryption code is generated éré and the analysis operation is repeated, then a third encryption code, etc. until 22 that the encryption code generated produces using the decoder lines, including those taken into account in the analysis, and for a determined group of frames, which do not start their image signal on the range of the deletion level chosen for the analysis with exceptions, the number of exceptions being less than a determined number, which leads to the end of the analysis and the storage of the last code used. 10. Device for implementing the method according to claim 1, characterized in that it comprises a) a synchronization extractor (1) which makes it possible to extract the line (2) and frame synchronization pulses (3 ) of the encrypted television signal received (100)? b) a circuit for analyzing cycle synchronization information (4), whether video or audio or both, and making it possible to generate cycle synchronization pulses? - c) a selector (20) to which the operator enters the delay value corresponding to his estimate of the offset value observed on the line analyzed? d) a memory (66) capable of storing each of the offset values selected by the operator at the selector, at a corresponding address of the cycle; e) a counter circuit (50) receiving the line synchronization pulses, frame and cycle as well as increment pulses & each validation of a new offset value at the selector, allowing, on the one hand to manage the memory and, on the other hand, to inform the frame selection circuit of the cycle frame, carrying the line being analyzed, to be selected; f) a frame selection circuit (9) which receives the frame information of the cycle to be selected from the counter circuit, as well as the line, frame and cycle synchronization pulses, and a video switch (5) controlled by the frame selection circuit, these two circuits being arranged so as to oc ocult for each of the cycles of T frames and for each frame value S select the line video information - but not the line or frame synchronization information - carried by the Tl frames different from that of the cycle which is to be selected and which, for its part, is fully transmitted. 11. Device according to claim 10 for the implementation of the method according to claims 2 and 3, characterized in that it further comprises circuits generating an index (11, 13, 15) marking the line being analyzed , and receiving from the counter circuit the line information to be selected and from the frame selection circuit the line synchronization pulses over the entire length of the selected frame, and a uniform gray level generator circuit (7) which transmits & instead of each of the line video information of the Tl frames of the cycle, "which are obscured by the video switch, a level signal corresponding to uniform gray. 12. Device according to claim 10 or 11, characterized in that it further comprises a suitable decoder (30) coupled with the memory (66) and which decrypts each of the lines of the cycle previously analyzed as a function of the respective offset values stored in memory and a logic circuit (40) associated with another video switch (41) for displaying on the screen the video information originating from the adapted decoder, the lines thus being decrypted when an offset value has been stored and not decrypted when the offset value coincides with that recorded on each reset of the memory and corresponding to a maximum offset, the adapted decoder then operating a zero compensation offset. 13. Device according to one of claims 10 to 12 for implementing the method according to claim 5, characterized in that the counter circuit (50) performs visual analysis only on n + 1 successive lines of the cycle, taken in a po- en o qu1 il CûvnvTer \ d> determined position of the cycle / A recognition circuit (55) - comprising a microprocessor controlled by the counter circuit and capable, at the end of the visual analysis, of comparing 24 n + 1 offset values stored in the memory (66) with each of the series of n + 1 offset values which it has in memory and which correspond to each of the different pseudo-random codes possible at this determined position of the cycle, and a pseudo-random code generator (61) to which it transmits information specific to the code which it has recognized, this generator then restoring the sought encryption code. 14. Device for implementing the method according to claim 6, characterized in that it comprises a) a synchronization extractor (1) which makes it possible • to extract the line synchronization pulses (2) and of the frame ( 3) the received encrypted television signal (100); b) a circuit for analyzing cycle synchronization information (4), whether video or audio or both, and making it possible to generate cycle synchronization pulses; - c) a code generator circuit (60), capable of * creating or successively reproducing all the different possible pseudo-random encryption codes and receiving the line, cycle and frame synchronization pulses; d) a suitable decoder (30) capable of applying a decryption delay to each line, as a function of the value of the encryption offset provided by the code generator, for a given code, successively for each of the lines of the cycle at the time of its respective passage; e) an image analysis circuit (300), to which is transmitted the version processed by the decoder, according to the code to be analyzed, of the initial encrypted video image, comprising: - a rejector filter (10) of the color subcarrier, making it possible to store video information only luminance; - a delay line (12), delaying a line period, responsible for delaying each video line to compare it with the next video line of the same frame; - a subtractor (16) responsible for subtracting the information 51 * 25 in order to keep only the difference; - at most d-1 selective frequency analysis channels, placed in squares, each one being specific to one of the d-1 different times this possible offset, the zero offset not being taken and. consideration, each vie comprising a band pass filter * 22) adapted to one of the d-1 possible offset times and a threshold level detector h with integrator (24); - a decision logic circuit (45) which, depending on the number of pulses received from threshold detectors with integrators (24), for a determined number of frames, informs the code generator that the code analyzed is the right one or no, this last interpretation leading to the analysis of another encryption code. 15. Device according to claim 14 for implementing the method according to claim 7, characterized in that it further comprises a transition counter consisting of:.? - a threshold detector (51), X - a bandpass filter (52), - a counter (53) to determine whether the contemporary video information of the analysis is favorable and to inform the logic decision circuit if the result given by the frequency selective analysis channels can be validated or not. 16. Device according to claim 14 or 15, characterized in that it further comprises: - a window generator (18) receiving the line and frame synchronization pulses responsible for switching the window switches (14,14 ' ) so as to keep only a certain number of lines of the input video signal for each frame and only a central part for each of these lines; - window switches (14,14 '), controlled by the window generator, one (14) being applied to the video signal from the subtractor (16) of the analysis circuit and / or the other (14' ) being applied to the video signal taken into account by the transition counter (51,52,53). 26 17. Device for implementing the method according to claim 9, characterized in that it comprises a) a synchronization extractor (1) which makes it possible to extract the line synchronization pulses (2) and of the frame ( 3) the received encrypted television signal (100); ; b) a circuit for analyzing cycle timing synchronization information (4), whether video or audio or both, and making it possible to generate cycle synchronization pulses; c) a code generator circuit (60), capable of successively creating or restoring all the different possible pseudo-random encryption codes and receiving the line, cycle and frame synchronization pulses; d) a suitable decoder (30) capable of applying a decryption delay to each line, as a function of the value of the encryption offset provided by the code generator, for a given code, successively for each of the lines of the cycle at the time of its respective passage; î e) an image analysis circuit (300 ′), to which is transmitted the version processed by the decoder, according to the code to be analyzed, of the original encrypted video image, comprising; - a rejection filter (10) of the color subcarrier, making it possible to store video information only the luminance; - a black alignment circuit (26) making it possible to restore the DC component of the signal; - a comparator circuit (27) which delivers a logic level 1 when the signal level is higher than a chosen reference level; - A window generator (18) making it possible to take into account in the analysis only certain lines for each frame and, for these lines, only a certain range of the suppression level, this window generator delivering a logic level 1 to within the time intervals taken into account in the analysis; - an "AND" logic gate (28) which processes the information coming from the window generator on the one hand, and from the comparator circuit on the other hand; Ψ 27 - a decision circuit (29) which, depending on the number of pulses received per given group of frames, informs the code generator of whether the code analyzed is the right one or not, this last interpretation entailing the analysis another encryption code.