RU2013024C1 - Method of television broadcasting with protection against unauthorized reception and system for its realization - Google Patents

Abstract

FIELD: television equipment. SUBSTANCE: method includes operations for isolation of synchronization pulses out of video signal, formation of new coded synchronization signals with their subsequent mixing into video signal, transmission of coded video signal over communication channel, extraction of coded synchronization signals from received video signal of formation of standard mixture of synchronization pulses and its connection with video signal. At transmitting side method includes operations of formation of new bipolar synchronization pulses, of formation of signal of first pseudorandom sequence, of signal of second pseudorandom sequence and of signal of third pseudorandom sequence. Then operations of addition of first and third PR sequences by their alternation and modulation of signal of bipolar synchronization pulses with signal of alternated PR sequence for generation of new coded synchronization signals are carried out. At reception side method involves operations of formation of signals of auxiliary frequency, of frequency of lines, fields and frames, of binary quantization of received video signal, of extraction of signal of frame synchronization pulse, of setting of phase of signals of frequency of lines, fields and frames in compliance with phase of frame synchronization pulse, of formation of signal of number of subscriber and of its comparison with signal of current phase position of formed signal of frame frequency with formation of comparison signal. After this operations of addition of comparison signal with binary-quantized video signal, of comparison of obtained summary signal with preset threshold value and of formation of signal of permission for scanning of coded video signal are conducted. System for realization of proposed method has input buffer, amplitude selections, phase discriminators, low-pass filters, voltage controlled generators, pulse generators, synchronization pulse former, keys integrator, unit for isolation of standard and input of new synchronization pulses, output amplifier, communication channel, referencing unit, selectors of field pulses, former of payment signal, payment memory unit, switch, selector of pulses of synchronization signal of receiver, integrator, selector of new synchronization pulses, decoder of payment signal, AND gate, coincidence circuit and pickup of subscriber's number. EFFECT: novelty of approach lies in insertion of coding of synchronization pulses by payment signal and their masking by means of series of pseudorandom sequences. 4 cl, 11 dwg

Description

 The invention relates to television and can be used in the construction of television broadcasting networks that are protected from unauthorized reception, for example, paid cable or terrestrial broadcasting networks.

 The purpose of the invention is to increase the effectiveness of preventing unauthorized admission.

 This is achieved by the fact that in a method of television broadcasting with protection against unauthorized reception, which includes coding on the transmitting side, the operation of removing clock pulses from the video signal, the formation of new encoded clock signals with their subsequent mixing into the video signal and transmission of the encoded video signal through the communication channel, and when decoding - on the receiving side, the selection of encoded clock signals from the video signal, for example, by the method of amplitude selection, the formation of a standard mixture of clock pulses and soy Inonii standard mixture sync with the video signal are introducing new operations.

According to the invention, when encoding on the transmitting side, the method includes operations of generating a signal of sync pulses bipolar with respect to the damping level, generating a signal of the first pseudo-random sequence with a frequency equal to f _p / n, generating a signal of a second pseudo-random sequence with a frequency equal to f _p / l, signal generation payment with a frequency equal to f _p / m, where n, l and m - positive numbers, the formation of the third pseudorandom sequence signal by logical processing of the signal ale ntov second pseudorandom sequence corresponding to the subscriber number of the subscriber payment signal, adding the first and third signals pseudorandom sequences interleaved at intervals of multiples of a lowercase upon a given law, and bipolar modulation signal interleaved clock signal for generating a pseudorandom sequence encoded new clock. When decoding on the receiving side, the method includes operations of constant generation of an auxiliary frequency signal with a frequency that is a multiple of the horizontal frequency of the selected encoded clock signal, generation of frequency signals of lines, fields and frames by dividing the auxiliary frequency signal. Also, when decoding, the operations of binary quantization of the received video signal at a level higher than the cancellation level are introduced to isolate the frame sync pulse by transversely filtering the binary quantized video signal, set the phase of the generated frequency signals of the lines, fields and frames in accordance with the phase of the selected frame sync pulse, generate a signal of the current phase position of the generated signal frame rates in relation to the selected frame sync pulse, the formation of a subscriber number signal, comp the signal of the subscriber number signal with the signal of the current phase position of the generated frame rate signal and the formation of a comparison signal. The operations of adding the obtained comparison signal to the binary quantized video signal, logically processed by the signal of the values of the elements of the second pseudo-random sequence for a given subscriber by the procedure of reverse logical processing of the signal of the second pseudo-random sequence by the payment signal on the transmitting side, comparing the received total signal with a given threshold value and generating a resolution signal are also performed viewing the encoded video signal in case of exceeding it.

 A feature of this method of television broadcasting is the formation of a clock signal, bipolar relative to the level of blanking. At the same time, their positive part is used to encode the payment signal and the synchronization signal, and the negative part is used for horizontal synchronization and the allocation of encoded clock signals from the video signal on the receiving side. A distinctive feature of the method is the generation of pseudorandom sequence signals (PSP), where the first SRP is used to encode the horizontal and frame synchronization signals, the second SRP is intermediate for generating the coded payment signal, i.e., the third SRP, by logically processing the signal of the second SRP with a true signal payment and the formation of the final coding signal by adding the signals of the first and third PSP by interleaving them at time intervals that are multiple of the line interval. Another distinctive feature of the solution is the formation of coded clock signals by modulating the bipolar clock signal with a final coding signal, i.e., an interleaved pseudorandom sequence signal.

 Namely the specified set and sequence of operations of the method leads to the achievement of the objective of the invention due to the repeated use of pseudo-random sequence signals, which greatly complicates the disclosure of the synchronization and payment code.

 In FIG. 1 and 2 show a structural diagram of the proposed system: in FIG. 3 is a block diagram of a clock generating unit; in FIG. 4 is a structural diagram of a pulse switch; in FIG. 5 is a structural diagram of a first pulse generator; in FIG. 6 is a structural diagram of a switch; in FIG. 7 is a structural diagram of a second pulse generator; in FIG. 8 is a structural diagram of a decoder of a payment signal; in FIG. 9 - time diagrams explaining the operation of the transmitting (encoding) part of the system; in FIG. 10 is a timing chart explaining the operation of the clock generation unit; in FIG. 11 is a timing diagram explaining the operation of the receiving (decoding) part of the system.

The proposed system contains a series-connected input buffer 1, the input of which is the input of the system, a first amplitude selector 2, a first phase detector 3, a first low-pass filter (LPF) 4, a first voltage controlled oscillator 5, a first pulse generator 6, a clock generating unit 7 , the first key 8, the combining unit 9, the block 10 removing standard and introducing new clock pulses, the output amplifier 11, the communication channel 12, the second key 13, the output of which is connected to the second input of the block 9, and the control input to the second output at block 7. Keys 8 and 13 must have potential inputs U ₁ and U ₂ . The system also contains a second block 14 binding, the input of which is connected to the input of the system, and the output is connected to the second input of the block 10. The first input of the block 10 is connected to the first output of the first generator 6, the fifth output of which is connected to the second input of the first phase detector 3, the first input which is connected to the input of the first selector 15 of the field pulses, the output of which is connected to the second input of the generator 6. Blocks 9 and 14 are equipped with latching inputs. The system also includes a driver 16 of the payment signal, the output of which is connected to the first input of the payment memory block 17, the second and third inputs of which are connected to the third and fourth outputs of the generator 6, respectively, and the output - to the control input of the block 7. The third and fourth outputs of the generator 6 should be connected to the second and third inputs of block 7, respectively. The system also contains a first block 18 binding, the signal input of which is connected to the output of the communication channel 12, and the output to the first input of the switch 19, the output of which is the output of the system. Block 18 has a latch level input, and its signal input is connected to a selector 20 and an integrator 22 connected in series, the output of which is connected to the second input of the switch 19. The output of the selector 20 is connected to a second phase detector 23, a second low-pass filter 24, and a second generator 25, voltage-controlled, the second pulse generator 26 and the third block 27 binding, the output of which must be connected to the fourth input of the switch 19 and which, like block 18, is equipped with an input level fixation. The first output of the generator 26 is connected to the first input of the phase detector 23. The system contains a second amplitude selector 28 and a new clock pulse selector 29 connected in series. In this case, the input of the selector 28 is connected to the output of the binding unit 18, and the output of the selector 28 is connected to the first input of the decoder 30 of the payment signal. The output of element And 31 is connected to the third input of the switch 19, the first input is connected to the output of the decoder 30, and the second input is connected to the second output of the generator 26. The first input of the coincidence circuit 32 is connected to the bus output of the second pulse generator 26, and the output is connected to the fifth input of the decoder 30. The low-order output of the subscriber number sensor 33 is connected to the second input of the coincidence circuit 32, and the output of the last high-order bit must be connected to the second input of the decoder 30. The output of the generator 25 is connected to the first input of the selector 29 and the third input of the encoder 30. The output of the selector 29 is connected to the second input of the generator 26. The third output of the generator 26 is connected to the fourth input of the decoder 30.

 The clock generating unit 7 comprises a first pseudo-random sequence (PSP) generator 34, a second PSP generator 35, a first sync pulse shaper 36, a second SI shaper 37, an inverter 38, and an EXCLUSIVE OR element 39 and a pulse switch 40 connected in series. At the first inputs of the generators PSP 34 and 35 and shapers 36 and 37 are fed with pulses of the horizontal frequency, the second inputs of the generator 34 and block 40 and the input of the inverter 38 are the pulses of the frame frequency, and the second inputs of the shapers 36 and 37 are pulses of the clock frequency. The inverter output is connected to the second input of the generator 35 and the third input of the block 40, the output of the generator 34 is connected to the fourth input of the block 40, the fifth and sixth inputs of which are connected to the outputs of the drivers 36 and 37, respectively. The output of the generator 35 is connected to the first input of the element 39, to the second input of which a payment signal is supplied. Pulse switch 40 is made on ten two-input logic elements AND 41.. . 50, two inverters 51 and 52 and four logical two-input elements OR 53.. . 56.

 The first pulse generator 6 contains a series-connected divider 57 by eight, the input of which is the first input of generator 6, the divider 58 by eight, the divider 59 by two, the shaper 60 of the blanking pulses and the element OR 61, the output of which is the first output of the generator 6. The output of the divider 57 is the second output of the generator 6, and the output of the divider 58 through the divider 62 by six hundred twenty five, the divider 63 by two and the driver 64 of the pulse frames 64 is connected to the fourth output of the generator 6. The output of the divider 59 is the third output for generators 6 and through the buffer 65 it is connected to a fifth output of the generator 6. The output of the divider 62 via a pulse shaper 66 fields coupled to a second input of OR gate 61, and adjusting the input divider 63 is connected to the second input of the generator 6.

 The switch 19 contains a series-connected element OR 67, an inverter 68, a key 69 and an output amplifier 70, the output of which is the output of the system, and the input is also connected to the output of the key 71, to the signal input of which a video signal is supplied. The signal input of the key 69 filed the clock signal SSP. The control input of the key 71 is connected to the output of the OR element 67, to one input of which a signal from the integrator 22 should be supplied, and to the other, the signal from the output of the And 31 element.

 The second pulse generator 26 contains a serially connected service pulse shaper 72, a strobe pulse generator 73, the output of which is the third output of the generator 26, a 1/625 divider 74 and a 1/2 1/2 divider connected in series, while the second output of the divider 74 is the low-order output of the bus the output of the generator 26, and the output of the divider 75 is the high-level output of the bus output of the generator 26, the SSP shaper 76 and the blanking mixture shaper 77, the shaper 76 output being the fourth gene output 26, and the output of the driver 77 is the second output of the generator 26. The second output of the driver 72 is the first output of the generator 26, and the third output of the driver 72 is with the first inputs of the divider 74 and the driver 76. The first output of the driver 72 is also connected to the second input of the driver 76 and the first input of the driver 77. The first output of the divider 74 is connected to the third input of the driver 76 and the second input of the driver 77. The first input of the driver 72 is the first input of the generator 26, the signal from the second input of which is fed to the second inputs of the generator ovatelya 72, divider 74 and divider 75.

 The decoder 30 of the payment signal contains a series-connected reversible counter 78, a D-flip-flop 79, an element EXCLUSIVE OR 80, an element AND 81, an integrator 82 and a comparator 83, the output of which is the output of the decoder 30, an inverter 84, the input of which is connected to the installation input of the counter 78 and is the fourth input of the decoder 30, and the output is connected to the counting input of the trigger 79, the threshold voltage source 85, the output of which is connected to the second input of the comparator 83. In this case, the first input of the block 30 is connected to the input for setting the data of the counter Single 78, the third input of the decoder 30 - with a positive counting input of counter 78. The second input unit 30 is connected to the second input member 80, and the fifth input of the block 30 - to a second input of AND gate 81.

 The proposed system works as follows.

When encoding a video signal from a video source, for example, a camera, a VCR (see Fig. 9, a) is fed through an input buffer 1 to the input of an amplitude selector 2, from the output of which a dedicated MSP (see Fig. 9, b) is fed to a phase detector 3 and a field pulse selector 15, inside which a field pulse is extracted by integration (see Fig. 9, b), and a pulse is generated at the output corresponding to the leading edge of the field pulse with a duration of less than 1/2 T _page (see Fig. 9, c). Phase detector 3, low-pass filter 4, generators 5 and 6 form a PLL loop. At the output of the generator 5 there are pulses of a clock frequency equal to 2 MHz in the example of a specific embodiment (see Fig. 9, e), and at the output of the generator 6, pulses f _cycles / 8 are phased due to the arrival of a pulse from the selector 15 (see Fig. 9), line frequency pulses (see Fig. 9, g) and frame frequency pulses. Inside the generator 6, a mixture of quenching pulses of lines and fields is also formed, which is fed to block 10 for removing standard pulses and introducing new clock pulses. The pulses f _clock / 8, the pulses of the horizontal frequency (see Fig. 10, a) and the pulses of frames with a duration of 13H (see Fig. 10, b) from the output of the generator 6 are sent to the block 7 of the formation of the clock signal, which also receives the payment signal from the block payment memory (see Fig. 10, c).

 Block 7 operates as follows (see Fig. 10).

The pulses of the lines and frames supplied to the generator 34 cause the formation of the signal of the first pseudo-random sequence during the frame sync pulse with a frequency of changing signal values equal to the horizontal frequency (see Fig. 10, g). The line pulses and inverted frame pulses supplied to the inputs of the generator 35 cause the second pseudorandom signal to be generated sequentially during the forward course of the frame as well as the horizontal frequency of changing the SRP signal values (see Fig. 10, e). The signal of the third SRP is obtained by logically processing the signal from the output of the generator 35 by the payment signal from block 17 on the EXCLUSIVE OR 39 logic element. The signal of the third SRP from the output of the element 39 is shown in FIG. 10. The pulses of the horizontal frequency (see Fig. 10, a and l) and the pulses f _clock / 8 (see Fig. 10, k) supplied to the input of the former 36 of the first clock pulse, cause the formation of the first clock pulse (see Fig. 10 , m). The same pulses arriving at the former 37 of the second clock cause the formation of a second clock (see Fig. 10, n), shifted by ≈Н (period f _clock / 8) relative to the first SR. In the pulse switch 40 (see Fig. 4), the synchronization signal of the first and third SRP is interleaved and modulated, as a result of which the first SRP modulates the clock signal in the interval of the frame sync pulse T = 13H, and the third SRP modulates the clock signal in the forward interval along the frame, which an example of a specific implementation is 612 lines, i.e., T = 612H. Thus, the entire clock signal is modulated by an interleaved pseudorandom sequence signal in the pulse switch 40. In this case, as a result of the processing by the pulse switch 40 of the pulses from the outputs of the drivers 36 and 37 (see Fig. 10, m and n, respectively) at the outputs of the pulse switch 40 leading to keys 8 and 13, modulated clock pulses appear, forming a clock signal (see Fig. 10, g and i). The clock pulses going to the key 8 (Fig. 10, g and k) always exist, and the clock pulses going to the key 13, then appear, then disappear depending on the content of the SRP (see Fig. 9, k and i). When an element of an interleaved SRP at the moment of the pulse existence is equal to a log. "1", then the pulse at the input of the key 13 exists, and if the element of the SRP is equal to the log. "0", then this pulse is absent (see Fig. 9, n and i). Another characteristic feature of the system is that when the element of the interleaved memory bandwidth is equal to the log. “0”, then the clock on the first output of block 7 takes the place of the clock on the second output of block 7, which at this moment is absent (see Fig. 10, g, and and Fig. 9, n). The pulses from the first and second outputs of the block 7 of the formation of the clock signal are supplied to the first 8 and second 13 keys. These keys form bipolar pulses, the combination of which allows you to create a bipolar clock signal. In this case, U ₁ supplied to key 8 should be lower than the blanking level (U _fix in block 9 of the association), and U ₂ supplied to key 13 should be higher than U _fix in block 9. In block 9, the pulses are combined, attached to the blanking level and then served on the block 10 removal of standard and the introduction of new clock pulses for insertion into the video signal instead of the standard clock pulses (see Fig. 9, l, a, m and n). These diagrams show how the standard clock pulses are replaced by new ones and the results of modulating new clock pulses of the interleaved memory bandwidth, which not only carries information about the payment, but also causes the failure of line synchronization among consumers who do not have permission to receive this program due to a jump-like shift of the line clock pulse by the value of H (in the example of a specific implementation of 4 μs) according to the law of a pseudo-random sequence.

 In the formation of the memory bandwidth, a payment signal is used (see Fig. 10, c), which is obtained during the interrogation of the payment memory block 17 with a horizontal frequency during a direct frame move, i.e., for 612 lines. The payment signal is entered into the payment memory block from the payment signal generator, which can be a keypad, or a personal computer can be used at the RS-232 interface if the corresponding program is available.

 The input video signal coming through the binding unit 14 to the standard removal unit 10 and introducing new clock pulses after introducing new encoded clock signals is supplied to the output amplifier 11, from the output of which it enters the communication channel 12. A communication channel is a modulator for transferring to a carrier, a communication line (cable or ether) and a receiver (demodulator) for restoring a low-frequency video signal.

The video signal (in / s) from the communication channel is fed to the binding unit 18 (see Fig. 2), where the blanking level is tied to the U _fix and from the output of the block 18 is fed to the switch 19 and the amplitude selector 28. The signal from the communication channel can come in two types - standard premium (see Fig. 11, a) and encoded premium with protection against unauthorized reception (see Fig. 11, a). Depending on the type of incoming signal, the receiving part of the system (descrambler) can operate in two modes. When the standard I / C is present at the input of the receiving part of the system, then the I / O from the descrambler input, which is input to the MSS pulse selector 20, is then fed to the input of the phase detector 23 and the field pulse selector 21 (see Fig. 11, b). At the output of the selector 21 fields there is a signal of field pulses (Fig. 11, c). This impulse is integrated by the integrator 22 and the constant potential coming from its output opens the switch 19 and allows the standard I / O to pass through the descrambler so that the owner of the descrambler built into the TV can watch ordinary television programs. At the same time, the signal displayed in FIG. 11d, which does not affect the operation of the system, since the signal is not scrambled initially. When at the input of the receiving part of the system there is a scrambled in / s (see Fig. 11, a '), then the picture changes significantly. At the output of the MSS selector 20, a signal is present in the form shown in FIG. 11, b ', and in this case, at the output of the field selector 21, the signal takes the form shown in FIG. 11 in '. At the same time, at the output of the second amplitude selector 28, which selects a signal that lies above the blanking level, there is a signal of the form shown in FIG. 11, d ', i.e., the signal of the so-called fourth SRP, representing the interleaving of the first SRP carrying information about the frame clock, the third SRP carrying information about the payment, and a random sequence obtained by binary quantization in / s. The signal from the output of the selector 28 is fed to the input of the selector 29 of the new clock pulses and the decoder 30 of the payment signal. At the same time, in the new SI 29 selector, a frame clock is distinguished by the transverse filtering method, the temporal position of which is determined by decryption, for example, a parcel in the form of a thirteen-digit Barker code of the form 1111100110101. If there is such a parcel in the fourth SRP received at the output of the selector 28, at the output of the new SI 29 a pulse appears, located in the interval of the frame quenching pulse and shown in FIG. 11, d. In this particular implementation example, we consider an option system designed for 612 subscribers, since with the number of lines in the frame equal to 625, to adequately isolate the frame clock, it is necessary to transmit it in the form of a 13-bit Barker code from the condition that the number of bits code is defined as N> logm = log625. This pulse (Fig. 11, e) is used for phasing over the frame of the second pulse generator 26 (see Fig. 7), which enters the PLL loop, formed by the phase detector 23, the low-pass filter, the generators 25 and 26. The second pulse generator 26 generates the entire nomenclature of pulses necessary for the operation of the television system, that is, the SSP pulses and the quenching mixture. In addition, the generator 26 generates a strobe pulse of duration t> 2 ^ H, existing during the horizontal blanking interval and shown in FIG. 11. Also, the generator 26 generates a line number code in the frame obtained by combining the codes of the least significant bits of this number obtained from the output of the divider 74 with the value of the highest bit received from the output of the divider 75. In this case, due to the operation of the PLL loop and the presence of a physicizing pulse over the whole frame the nomenclature of pulses in the receiving part of the system is formed synchronous with respect to the pulses of the transmitting side of the system, while the clock frequency, like on the transmitting side, is 2 MHz and the interval H, respectively, is 4 μs.

Since each of 612 subscribers is tied to the line with the corresponding number on the transmitting side and the payment signal relating to this subscriber is transmitted on this line, the permission to view this subscriber on the receiving side is formed taking into account this factor. Therefore, the line number code from the generator 26 is supplied to one of the inputs of the coincidence circuit 32 (digital comparator). A code from the sensor 33 of the subscriber number is supplied to another input of the coincidence circuit 32, the last senior bit of which carries information about the value of the second SRP for a given line number (i.e., for a given subscriber number) in the transmitting part of the system and is fed to the input of the signal decoder 30 payment. When the codes match, the pulse generated in FIG. 11, g, lasting one line once per frame. For different subscribers, the position of this pulse in the frame interval is different. This pulse is fed to the fifth input of the decoder of the payment signal (see Fig. 8). The second input of the decoder 30 receives the signal of the highest category of the subscriber number code mentioned above. Also, the inputs of the decoder 30 receive pulses from the selector 28 (Fig. 11, g '), from the generator 26 (Fig. 11, e) and pulses of the clock frequency. The pulse from the selector 28 (Fig. 11, d) prohibits or permits the action of the clock sequence - f _clock from the generator 25 depending on the content of the payment signal of the prisoner in the fourth SRP at the intervals of the horizontal blanking pulses during the direct passage through the frame on the interval 612H (612 lines by the number of subscribers). In the case when the payment signal is log. "1" (see Fig. 11, g ') the clock cycle is allowed, the counter 78 is reset at the R-input by the previous pulse state in Fig. 11, c, arriving at the D-input of the counter 78, in the decoder 30. At the time of the occurrence of the strobe pulse (Fig. 11), the counter 78 at the R-input also has a resolution on the account. The clock pulses during the time ^ H will be able to go through eight times and the input of the S-flip-flop 79 receives a pulse from the counter 78 and cockes the trigger. The trigger is reset by an inverse pulse from block 26. In this way, a signal is generated that repeats the signal of the third SRP on the transmitting side with a duration of one line, i.e., a payment signal encoded by the second SRP is generated (see Fig. 11, and). The elements of the second PSP (its values) are spaced according to the subscriber numbers and are wired for each subscriber in the highest category of the subscriber number, which from the sensor 33 of the subscriber is fed to the input of the decoder 30 of the payment signal. The signal from the sensor 33 is constantly supplied to the second input of the EXCLUSIVE OR 80 element of the decoder 30 and the signal at its first input restores the true payment signal at the output of the element 80. The true payment signal is supplied to one of the inputs of the And 81 element, to the other input of which there is a pulse from the output of the 32 matches pattern. In the presence of both one and the other impulses, an impulse is formed at the input of the And 81 element (see Fig. 11, k), i.e., if the subscriber is paid. These pulses arrive once per frame on the integrator 82, turn into a constant voltage and if they arrive continuously through several frames (for example, three), the voltage at the output of the integrator 82 exceeds the voltage at the output of the threshold voltage source 85 and at the output of the comparator 83 a viewing permission signal is generated. In this case, through the element And 31 from its second input passes a mixture of quenching pulses from the second output of the pulse generator 26. This mixture of damping pulses permits the passage of the video signal from the binding unit 18 to the input of the output amplifier 70 in the switch 19 through the key 71 during a straight line travel. During the reverse stroke along the line to the input of the output amplifier 70 through the key 69 receives the clock signal SSP from the driver SSP 76 in the pulse generator 26 through the block 27 binding. At the input of amplifier 70, the SSP video signal is added by embedding the SSP into the video signal at the blanking intervals, taking into account that both the SSP and the video signal have the same reference levels.

Claims (3)

1. A method of television broadcasting with protection against unauthorized reception, in which the standard clock pulses are extracted from the video signal on the transmitting side, new clock signals are generated, followed by their encoding and mixing into the video signal, which is transmitted via the communication channel, and new encoded clock signals are extracted from the received side video signal, form a standard mixture of clock pulses and mix a standard mixture of clock pulses with a video signal, characterized in that on the transmitting side new syn roimpulsy form bipolar relative to blanking level, form the signal of the first pseudo-random sequence with the frequency f _p / n, forming the signal 3 in the second pseudo-random sequence with a frequency equal to f _p / l, is formed a payment signal with the frequency f _p / m, where n, m, l - positive numbers, form the signal of the third pseudo-random sequence by processing the signal of the elements of the second pseudo-random sequence corresponding to the subscriber number, the payment signal of this subscriber, add the signals of the first and by moving a series of pseudo-random sequences by moving them at intervals that are multiple of the horizontal line according to a given law, and modulate the bipolar clock signal with a moved pseudo-random sequence signal to obtain new encoded clock signals, and on the receiving side, a auxiliary frequency signal is generated continuously with a frequency multiple of the horizontal line frequency of the extracted new encoded clock signals frequency signals of lines and frames by dividing the auxiliary frequency signal, binary quantize when the captured video signal at a level higher than the blanking level, the frame clock is isolated by transversally filtering the binary quantized video signal, the phase of the generated line and frame frequency signals is set in accordance with the phase of the selected frame clock, the current phase position signal of the generated frame frequency signal is generated relative to the selected frame clock, form the subscriber number signal, compare the subscriber number signal with the signal of the current phase position of the generated s Nala frame rate and generating a comparison signal, the resulting summed signal from the comparison binary quantized video signal processed by the signal values of the elements of the second pseudo-random sequence, the resulting sum signal is compared with the threshold value and generating a signal permits the encoded video viewing in the event of exceedance.  2. System for television broadcasting with protection from unauthorized reception, containing a series-connected input buffer, the input of which is the input of the system, a first amplitude selector and a first phase detector, as well as a series-connected first voltage-controlled oscillator, a first pulse generator, a standard sync pulse allocation unit , an output amplifier, a communication channel, a first binding unit and a switch, the output of which is the output of the system, as well as a second binding unit, the input of which is connected n with the input of the first amplitude selector, and the output with the second input of the standard clock selection block, a clock generation unit, the first, second and third inputs of which are connected to the second, third and fourth outputs of the first pulse generator, respectively, an integrator whose output is connected to the second input a switch, a second phase detector and a second voltage-controlled oscillator and a second pulse generator connected in series, the first output of the first and first output of the second impu xy are connected to the second input of the first and first input of the second phase detectors, respectively, characterized in that a first field pulse selector is introduced into it, the input of which is connected to the output of the first amplitude selector, and the output is connected to the second input of the first pulse generator, payment signal conditioner, output which is connected to the first input of the payment memory unit, the second and third inputs of which are connected to the third and fourth outputs of the first pulse generator, respectively, and the output to the control input of the unit a clock signal, the two outputs of which are connected to the control inputs of the first and second keys, the potential inputs of which are connected to the first and second inputs of the combining unit through these keys, and the output of the combining unit is connected to the third input of the block for removing old and introducing new clock pulses, and a selector is introduced pulses the clock signal of the receiver (SSP) and the second amplitude selector, the decoder of the payment signal and the element And, the output of which is connected to the third input of the switch, and the second input from the second the output of the second pulse generator, the bus output of which is connected to the first input of the match system, the other input of which is connected to the bus output of the least significant bits of the subscriber number sensor, the last senior bit of which is connected to the second input of the payment decoder, the third input of which is connected to the output of the second voltage-controlled generator , and the first input of the selector of new clock pulses, the output of which is connected to the second input of the second pulse generator, the third output of which is connected to the fourth input of the decoder ra of the payment signal, the input of the first binding unit is connected to the input of the SSP pulse selector, the output of which is connected to the second input of the second phase detector, and through the second field pulse selector to the integrator input, while the outputs of the first and second phase detectors through the first and second lower filters frequencies (low-pass filters) are respectively connected to the inputs of the first and second generators controlled by voltage, and the output of the second pulse generator through the third binding unit is connected to the fourth input of the switch, and the inputs of level f the ixings of the first, second, third binding units and the combining unit are combined and the fixing level potential is applied to them, while the input of the second amplitude selector is connected to the output of the first binding unit, and its output is connected to the second input of the new clock pulses selector.  3. The system according to claim 2, characterized in that the clock generating unit is made in the form of generators of the first and second pseudorandom sequences, shapers of the first and second clock pulses, an inverter and a series-connected EXCLUSIVE OR element and a pulse switch, with the first inputs of the first and second generators pseudo-random sequences and shapers of the first and second sync pulses, line frequency pulses are applied, to the second inputs of the generator of the first pseudo-random sequence and, the pulse switch and the inverter input are supplied with frame-frequency pulses, clock pulses are applied to the second inputs of the first and second clock pulses, the inverter output is connected to the second input of the second pseudorandom sequence generator and the third input of the pulse switch, the output of the first pseudorandom sequence generator is connected to the fourth input pulse switch, the fifth and sixth inputs of which are connected to the outputs of the shapers of the first and second clock pulses, respectively -retarded and the generator output of the second pseudo-random sequences is connected to a first input of the EXCLUSIVE OR gate, the second input of which is served by the payment signal and two outputs are the outputs of the switch pulse forming unit clock.

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