RU2108677C1 - Radio noise shaping device - Google Patents

Abstract

FIELD: radio engineering; man-made noise generation. SUBSTANCE: known radio-noise shaping device is provided, in addition, with transmission intensity detecting unit and time interval shaping unit which function to measure intensity of frame transmission in suppressed channel, to shape length- adequate radio-noise radiation cycle, and to shape emitted misinforming pulse train. Device shapes spot misinforming jamming including characteristic features of channel-level data transmission protocols. EFFECT: reduced time of radio noise radiation to ensure desired degree of disturbance of data transmission channel being suppressed. 3 cl, 7 dwg

Description

 The invention relates to the field of radio engineering, and in particular to the technique of creating artificial interference and, in particular, can be used as a simulator of an interfering signal when setting up and evaluating the throughput of data transmission networks.

 Known devices for the formation of radio interference [1 and 2]. Design schemes for such devices include antennas, antenna switches, signal detection and analysis equipment, jamming devices, control equipment, and an interference transmitter. These devices are capable of emitting radio noise continuously or "in response" to relatively long (≥ 2s) messages, which leads to unjustified expenditure of power and time of radiation on the disorganization of the suppressed radio network.

 The closest in its technical essence to the application is a jamming device [2]. The prototype device includes an antenna system with an antenna switch, detection equipment, consisting of a receiver and an analyzer of technical (spectral, structural) characteristics of the signal, an interference generating device, control equipment, an interference transmitter. With this scheme, the receiver (as a rule, with the automatic search for signals by frequency, space and time) serves to detect the radiation of the XPS, select the signal, amplify it and process it. The analyzer is used for the technical analysis of the parameters of the detected signals and the choice of the interference structure. Based on the analysis of the signals, a decision is made to create interference. The jamming device is used to form various types of interference and their structures for typical signal structures of electronic equipment. The control equipment is used to collect, process information about the signals and their sources, display the signal and interference together on the indicators, ensure the necessary accuracy of the interference guidance to the signal, and also to turn on the interference station. The interference transmitter emits continuous or pulsed modulated high-frequency oscillations of the required power in a given frequency range. Depending on the parameters of the received signal, the control equipment selects the most effective type of interference, generates voltages that control the operation of the transmitter, and tunes the transmitter to the operating frequency of the suppressed station. This ensures the formation of an aiming in frequency, time and space of the radio noise with one of the available types of modulation. The known device is focused on the creation of radio interference in networks that implement the principles of switching channels.

 However, a known device has disadvantages. So, when suppressing modern digital radio networks based on the principles of message switching, the following disadvantages are found in such a device: it is impossible to create a response interference due to the short durations (10-100 ms) of the messages and significant hardware delays of the interference station, which leads to unjustified costs for continuous interference radiation; the control equipment does not react in any way to the transmission intensities in the channel and the features of the protocols used in it.

 The aim of the invention is to develop a device for the formation of radio interference, which provides the creation of targeted deliberate interference, taking into account the features of the protocols for the transmission of information channel level.

 This goal is achieved by the fact that in the known device for the formation of interference, comprising an antenna system with an antenna switch, control units, detection and analysis, interference generation, and an interference transmitter, the output of which is connected through the first input of the antenna switch to the antenna system, and its first input is connected with the first output of the jamming unit, the first input of which is connected to the first output of the control unit, the second, third and fourth outputs, which are connected respectively with the second inputs of the interference transmitter, antenna of the switch and the detection and analysis unit, the first input of the latter via the output of the antenna switch is connected to the antenna system further introduced blocks determining the intensity and transmission time slots forming. In the proposed device, the first and second inputs of the transmission intensity determination unit are associated with the output of the detection and analysis unit and the fifth output of the control unit, and the first, second, third and fourth outputs of the transmission intensity determination unit are connected with the corresponding inputs of the time interval formation unit, output and additional the fifth input of which is connected respectively to the second input and second output of the jamming unit.

 The transmission intensity determination unit consists of a forming device including cascade-connected amplifier-detector and amplifier-limiter, element "And", the first, second and third shift register, storage register, comparator, the first and second one-shots with restart, the first and second element OR, first and second trigger and clock. The input of the forming device is connected to the output of the detection and analysis unit, and the first output of the amplifier-detector is connected to the output of the amplifier-limiter, the output of which is supplied to the first input of the "AND" element, the second input of which is connected to the output of the second trigger and the first input of the second element "OR " The output of the element "And" is fed to the first input of the first shift register, the second input of which is connected to the output of the first trigger and the second input of the second trigger. The output of the first shift register is connected to the first inputs of the first trigger and the second shift register, the second input of the latter is connected to the output of the second one-shot, the input of which is connected to the fifth input of the storage register and the second output of the clock generator, the first output of which is fed to the second input of the second element "OR "whose output controls the second input of the first trigger. The input of the clock generator is connected to the first input of the second trigger and the output of the first "OR" cell, the second input of which is controlled by the "INSTALL" signal coming from the fifth output of the control unit, and the first input of the "OR" element is connected to the output of the first one-shot, the input of which is connected to the second output of the amplifier-detector. The first, second, third and fourth outputs of the second shift register are connected to the corresponding inputs of the storage register, the first, second, third and fourth outputs of which are fed to the corresponding inputs of the comparator, the fifth, sixth, seventh and eighth inputs of which are connected respectively to the first, second, third and the fourth outputs of the third shift register. The first, second and third outputs of the comparator are fed to the corresponding inputs of the time interval forming unit, to the fourth input of which the third output of the clock generator is connected.

 The block for the formation of time intervals consists of the first, second, third, fourth and fifth elements “And”, the first, second and third waiting multivibrators, the first and second cells “OR”, the storage register, shift register, the first and second counter, the element “NOT” "and a single pulse shaper. The first inputs of the first, second and third "And" elements are connected respectively to the first, second and third outputs of the gear intensity determination unit, and their second inputs are interconnected and connected to the second input of the fifth "And" element, the second output of the jamming unit and the input shaper of a single pulse, the output of which is connected to the second inputs of the first and second counters and the output of the last, the outputs of the first, second and third element "And" are fed to the inputs of the corresponding waiting multivibrators, the outputs of which are connected to the corresponding inputs of the first element "OR, the output of which is fed to the first input of the fifth element" AND ", the output of which is connected to the second input of the block of formation, interference, the third input of the fifth element" AND "is connected to the first input of the second counter and the output of the second element" OR ", the second input of which is connected to the output of the fourth element" AND ", the second input of the latter is connected to the output of the element" NOT ", the input of which is connected to the tenth input of the shift register and the output of the first counter, the first input of which is connected to the first input tvertogo element "AND", the fourth output intensity determination unit transmissions and ninth input shift register, the first to eighth inclusive inputs connected with respective outputs of the storage register of the shift register output is supplied to a first input of a second "OR" cell.

 The listed new set of essential features ensures, by periodically determining the intensity of transmission of messages transmitted over the suppressed channel, the formation of misinforming interference emissions adequate in their intensity, bringing the total traffic of the channel to its theoretical limit. In practice, this will lead to the fact that the size of the queue, consisting of messages ready for transmission, and the time they wait for access to the channel will tend to infinity.

 In FIG. 1 shows a general block diagram of a radio interference generating apparatus; in FIG. 2 and 3 are a block diagram of a gear intensity determination unit; in FIG. 4 is a structural diagram of a block for forming time intervals; in FIG. 5 is a block diagram of a detection and analysis unit; in FIG. 6 is a block diagram of a control unit; in FIG. 7 is a block diagram of a jamming unit.

 The radio noise shaping apparatus shown in FIG. 1 includes an antenna system (AS) with an antenna switch (AK) 1, detection and analysis units (BOA) 2, control units (BU) 3, jamming (BFP) 5, determining the transmission intensity (BOMP) 6, forming time intervals (BFVI ) 7 and the interference transmitter (PP) 4. The output of 113 AC with AK 1 is connected to the output 121 of BOA 2, and the output of 111 AC with AK 1 is connected to the output of 143 PP 4. The outputs 131 - 135 of BU 3 are connected respectively to the inputs of 152 BFP 5 , 142 PP 4, 112 AC with AK 1, 122 BOA 2 and 162 BOIP 6. Output 123 BOA 2 is fed to input 161 BOIP 6, outputs 163 - 166 of which are connected respectively to inputs 171 - 174 of BFVI 7. Output 176 B VI 7 connected to the output 153 of the BFN 5, outputs 151 and 154 which are respectively connected to input 141 and input PP 4 175 BFVI 7.

 The gear intensity determination unit, the circuit of which is shown in FIG. 2, consists of an amplifier-detector 601, an amplifier-limiter 602, an And element 603, shift registers 604, 605 and 611, a storage register 606, a comparator 607, single-vibrators 608 and 615, OR elements 609 and 614, triggers 610 and 613, a clock generator (GTI) 612.

 The input 3 of the amplifier-detector 601 is connected to the output 123 of the BOA 2, and its input 1 is connected to the input 1 of the amplifier-limiter 602, the output 2 of which is connected to the input 1 of the And element 603. The input 2 of the AND element 603 is connected to the output 3 of the trigger 613 and the input 1 of the OR element 614, the output 2 of which is connected to the output 1 of the GTI 612. The output 3 of the And element 603 is supplied to the input 1 of the shift register 604, the input 2 of which is connected to the output 3 of the trigger 610 and the input 2 of the trigger 613. The output 3 of the shift register 604 is connected to the input 1 of the shift register 605 and the input 1 of the trigger 610, input 2 which is associated with the output 3 of the element 614 "OR". The output 2 of the shift register 605 is connected to the output 4 of the one-shot 615, the input 3 of which is connected to the input 5 of the storage register 606 and the output 2 of the GTI 612. The outputs 3-6 of the shift register 605 are supplied respectively to the inputs 1-4 of the storage register 606, outputs 7-10 which are connected respectively with the inputs 8-11 of the comparator 607. The inputs 4-7 of the comparator 607 are connected respectively to the outputs 1-4 of the shift register 611. The outputs 1-3 of the comparator 607 are connected respectively to the inputs 171-173 of the BFVI 7. Output 2 of the amplifier-detector 601 fed to input 3 of a single vibrator 608, output 4 of which with input 1 of element 6 09 "OR", output 3 of which is connected to input 1 of trigger 613 and input 4 of GTI 612, output 3 of which is fed to input 174 of BFVI 7. Input 2 of element 609 "OR" is connected to output 135 of control unit 3.

 The time interval generating unit, the circuit of which is shown in FIG. 3, consists of AND elements 701-703, 708, and 713, waiting for multivibrators 704-706, OR elements 707 and 714, storage register 709, shift register 710, counters 711, 715, NOT element 712, and a shaper a single pulse 716. The inputs of 1 elements 701-703 "And" are connected respectively to the outputs 163-165 BOIP 6, and the outputs of 2 elements 701-703 are interconnected and connected to the input of 2 elements 708 "And", the output 154 of the BFP 5 and the input 1 of the shaper 716. The outputs of 3 elements 701-703 are connected to the inputs 1 of the waiting multivibrators 704-706, the outputs 2 of which are supplied respectively to the inputs 1-3 of the element 707 "OR", the output d 4 which is connected to the input 1 of the element 708 "AND". Input 9 of shift register 710 is connected to input 1 of element 713 AND, output 166 of BOIP 6 and input 1 of counter 711, output 3 of which is connected to input 1 of element 712 "NOT" and input 10 of shift register 710. Output 2 of element 712 "NOT" "connected to the input 2 of the element 713" AND ", the output 3 of which is fed to the input 2 of the element 714" OR ". The outputs 1-8 of the register 709 are connected respectively with the inputs 1-8 of the shift register 710, the output of which 11 is connected to the output 1 of the element 714 "OR". The output 3 of the OR element 714 is connected to the input 3 of the AND element 708 and the input 1 of the counter 715, the output 3 of which is connected to its second input, the input 2 of the counter 711 and the output 2 of the shaper 716. The output 4 of the 708 I element is fed to input 153 BFP 5.

 The elements of the described blocks are known and can be implemented on the industry-produced microcircuits of the series: 133, 523 and 555. As components of the detection and analysis unit 2 shown in FIG. 4, the R-330UPP and the P-399T analyzer produced by industry can be used. As the output 123 of BOA 2, the standard output of the intermediate frequency of the soft starter can be used. The control units 3 and interference generating units 5 included in the device, shown respectively in FIG. 5 and 6, are built according to well-known schemes and are described in detail in the technical description of industrial designs of radio interference of the P-330 series.

 The proposed device operates as follows. The control unit 3 organizes the operation of the entire device in several periodically repeating cycles.

 In the intelligence cycle, BU 3 puts BOA 2 in automatic search mode. Upon detection of the soft starter of the source of radio emissions (IRI), BOA 2 determines the value of the carrier frequency and the code of this value is sent to BU 3 for analysis of its presence in storage devices (memory). If the code of this frequency has already been recorded in one of the memory, then BU 3 gives the RESET command to the soft starter and the search for new IRI is resumed. When a new IRI is detected, the code of its frequency after a similar check is recorded in the memory of the control unit 3, the search stops, the soft starter saves the setting, and the operator has the ability to control and analyze the received signal using the analyzer (Fig. 4). The decision to suppress this IRI is made by the operator according to the results of the analysis. Then, at the command of the operator, codes of this frequency and type of transmission are recorded in the block of memory of the suppressed frequencies (BCH) (Fig. 5). After the reconnaissance cycle, BU 3 transfers the device in control mode.

 In the control cycle from BU 3, the input code of the BOA 2 is transmitted to the input 122 of the BOA 2 and at the same time the “INSTALL” command to the input 162 of the BOIP 6. The BOA 2 is tuned according to the received code to the given frequency and, in case of IRI operation, gives a radiation presence signal to the BU 3 . At the same time, the IF signal from the output of 123 BOA 2 is fed to input 161 of the BOIP 6 and then to the forming device (FU). FU converts the input signal voltage to pulses with steep edges, the amplitude and shape of which do not depend on the shape and amplitude of the input signal. The sequence of generated FU pulses from the output 2 of the amplifier-limiter 602 is fed to the input 1 of the element 603 "And". At its other input 2, from output 3 of the counting trigger 613, a signal is received that permits operation in the pulse counting mode. The latter is controlled by the signal "SET" (at each transition to another frequency in control mode), which is fed from the output 135 BU 3 to the input 162 BOIP 6 and then to the input 2 of the element 609 "OR". From the output 3 of the element 609, this command is fed to the input 1 of the trigger 613, setting it to state "I". By the same command, the input 4 of the GTI 612 is locked for the entire period of the counting and the formation of the reference interval begins (at the output of 2 GTI 612), which is a pulse of negative polarity. Upon receipt of the enable signal "I" at input 2 of element 603 from its output 3, the analyzed pulse sequence is fed to input 1 of the bit register 604. In the proposed embodiment, the device is decided on the presence of frame transmission in the channel when the level "I" appears in the upper bit of register 604 (on the eighth impulse). The signal "I" from the output 3 of the register 604 goes to the input 1 of the register 605 and to the input 1 of the trigger 610, which goes into the state "I" and with its output signal resets the register 604 and the trigger 613 to the state "O", thereby prohibiting the calculation of receive the remaining pulses of the current frame. After that, the leading edge of the nearest pulse from the GTI 612 meander coming from the output 1 of the GTI, through the element 614 "OR", the trigger 610 is transferred to the state "O", which ensures the preparation of the register 604 for the next account. The counting of pulses of the next frame begins with the appearance of the leading edge of this frame, which is supplied from the output 2 of the amplifier-detector 601 to the input 3 of the single-shot 608 with a restart, which at the output 4 generates a single short pulse. This pulse through the element 609 "OR" puts the trigger 613 in the state "I", which ensures the resolution of the next stage of the account. At the end of receiving the current frame, the single-shot 608 does not respond to the reverse voltage drop at the output 2 of the amplifier-detector 601 and saves the zero state at its output 4 until the next frame appears. Thus, from the output 3 of the shift register 604, a signal consisting of a sequence of unit pulses with random time intervals between them, which is equivalent to the number of frames transmitted in the monitored channel, is fed to input 1 of the register 605 operating in counter mode of 8. The duration of the counting interval, defined by the signal of the reference interval formed at the output 2 of the GTI 612 and which, as already noted by the pulse of negative polarity, is produced so that it fits into the duration of the period during which o The soft starter saves the setting at a controlled frequency. At the end of the interval for measuring the transmission intensity in the channel, the trailing edge of the pulse of the reference interval (positive polarity) is fed to input 5 of register 606 as a command to write information to the register 606 from the outputs of register 605. In addition, the same edge is applied to input 3, a single vibrator 615 is triggered, which at its output 4 generates a short pulse of negative polarity necessary to detect the register 605. The information recorded in the register 606 of storage in it until the end of the next interval of measurement of intensity and gears in the channel. In the future, it is used for the operation of the comparison device, which allows you to decide on the required duration of the interval of radiation of the interference sequence. The comparison device is assembled on storage registers 606, 611 and comparator 607. A number is written in binary form to storage register 611, the value of which can be constant or interchangeable. At the end of the counting interval and recording information in the register 606 at its outputs 7-10 appears recorded in binary form, the value of the number of transmissions. Using the comparator 607, the numbers stored in the registers 606 and 611 are compared, as a result of which, immediately after the end of the counting interval, an “I” signal appears on one of the outputs 1-3 of the comparator 607, indicating the following transmission intensities in the channel: if output 1 is the intensity gears more than set; if at the output 2 - the measured transmission intensity is equal to the specified; if at the output 3 - the transmission intensity in the channel is less than the specified value.

 After the end of the control cycle BU 3 through the output 131 gives the command settings of the pathogen, arriving in the BFP 5 from the input 152. After its execution, the radiation cycle begins. Depending on the intensity of the frame transmission in the channel, that is, when the “I” signal appears on one of the outputs of the 163-165 BOIP 6 connected respectively to the inputs 171-173 of the BFVI 7, the time interval generation unit allows the selection of the corresponding radiation interval duration. This selection and the formation of an interference sequence of pulses is as follows. The signal "I" supplied to the input 1 of one of the elements 701-703 "AND" BFVI 7 provides the selection of the appropriate multivibrator 704-706, and the formation of this multivibrator the required interval of radiation time begins with the appearance of the input 175 of the BFVI 7 command "PRD". This command, arriving at the inputs of 2 elements 701-703, passes only through one of them, having a signal "I" at its input 1, and starts the corresponding multivibrator. In addition, the command "PRD" with its leading edge ensures the start of the driver 716, the leading edge of a single pulse of which resets the counters 711 and 715 to zero, which ensures the initial moment of formation of the desired pulse sequence. Coming to the input 2 of the element 708 "And", the command "PRD" permits the passage of the pulse sequence generated at the output 3 of the element 714 "OR", which, entering the input 3 of the element 708 "And", passes to its output 4 only during the time interval set by running multivibrator. The required pulse sequence is formed as follows. The input 174 BFVI 7 output 166 BOIP 6 from the GTI 612 receives a meander that sets the transmission speed. The pulses of the meander are fed to the input 1 of the element 713 "AND", the input 9 of the shift register 710 and the input 1 of the counter 711 to 64. Until the signal "I" appears on the output 3 of the counter 711, the element 712 "NOT" allows the passage of the meander through the element 713 "AND" to the input 2 of the element 714 "OR". After counting 64 pulses at the output 3 of the counter 711, the signal “I” appears, which simultaneously stops the passage of the meander through element 713 and the start (by input 10 of register 710) of reading the specified sequence from the storage register 709. The shift register 710 is a register with parallel input and serial output of information. The output of the pulse train simulating the flag is controlled, that is, with the speed of the meander supplied to the input 9 of register 710. Thus, the sequence of flag pulses is fed to input 1 of element 714 immediately after the count ends at 64, which leads to output 3 of the “OR” element 714 of the 65th pulse, since the flag is a binary combination 01111110. From the output 3 of the element 714, the signal generated in the described way is fed to the input 1 of the counter 715 by 65. With the appearance of “I” on its output 3, the counter 711 and 715 are reset to zero state, providing the beginning of the formation of the next sequence of impulses, similar in structure.

 The set of pulses from the output 3 of the element 714 goes to the input 3 of the element 708. If there are two other enable signals at the inputs 1 and 2, this sequence passes to the output 176 of the BFVI, and then through the input 153 of the BFV 5 to its modulating signal device (Fig. 6) , which provides modulation of the pathogen by the received signal. After the suppression cycle, the control unit 3 interrupts the transmission mode, at the end of which the BFP 5 removes the “PRD” command from the input 175 of the BFVI 7. Next, the operation cycles of the radio noise generating device are repeated.

Claims (3)

 1. A radio interference generating device comprising an antenna system with an antenna switch, control, detection and analysis, interference generating units and an interference transmitter, the output of which is connected to the first input of the antenna system with an antenna switch, and its first input is connected to the first output of the interference generating unit, the first input of which is connected to the first output of the control unit, the second, third and fourth outputs of which are connected respectively to the second inputs of the interference transmitter, antenna system with antenna switch and node detection and analysis, the first input of which is connected to the output of the antenna system with the antenna switch, and the fifth output of the detection and analysis unit is connected to the first input of the control unit, characterized in that the fifth output of the control unit is connected to the third input of the detection and analysis unit, first, second , the third and fourth outputs of which are connected to the corresponding additional inputs of the jamming unit, consisting of n pathogens, n> 2, a block of modulating signals, a transmission control unit, a switch and a block formed time intervals, the first input of which is connected to the first output of the transmission control unit, and the second input is combined with the second input of the block of modulating signals, the second input of the transmission control unit and the first inputs of pathogens, together making up the first input of the interference generating unit, the other four inputs of the temporary generating unit intervals are additional inputs of the interference shaping unit, the output of the time interval forming unit is connected to the first input of the block of modulating signals, the first output of and the transmission control is connected to the first input of the switch, the output of which is combined with the second output of the transmission control unit and is the first output of the jamming unit, and the i-th output of the block of modulating signals, where i = 1, 2, ..., N, is connected to the second input of the i-th exciter, the output of which is connected to the corresponding input of the switch, the detection and analysis unit consists of a direction finding device, the first and second inputs of which are respectively the first and second inputs of the detection and analysis unit, and its second and first the th outputs are connected respectively to the analyzer input and the first input of the transmission intensity determination unit determination block, the second input of which is the third input of the detection and analysis unit, and its first, second, third and fourth outputs are the corresponding outputs of the detection and analysis unit, the analyzer output is the fifth the output of the detection and analysis unit and is connected to the first input of the control unit.  2. The device according to claim 1, characterized in that the unit for determining the transmission intensity is made in the form of series-connected amplifier-detector and amplifier-limiter, forming a forming device, the input of which is connected to the output of the detection and analysis unit and is the first input of the unit for determining the transmission intensity and the output of the amplifier-limiter is connected to the first input of the AND element, the second input of which is connected to the output of the second trigger and the first input of the second OR element, the output of the And element is connected to the first input the first shift register, the second input of which is connected to the output of the first trigger and the second input of the second trigger, the output of the first shift register is connected to the first input of the first trigger and the first input of the second shift register, the second input of the last is connected to the output of the second one-shot, the first input of which is connected to the fifth the input of the storage register and the second output of the clock generator, the first output of which is connected to the second input of the second OR element, the output of which is connected to the second input of the first trigger, input the clock generator is connected to the first input of the second trigger and the output of the first OR element, the second input of which is the second input of the transmission intensity determination unit, and the first input of the first OR element is connected to the output of the first one-shot, the input of which is connected to the second output of the amplifier-detector, the first, the second, third and fourth outputs of the second shift register are connected to the corresponding inputs of the storage register, the first, second, third and fourth outputs of which are connected to the corresponding inputs of the com paratora, the fifth, sixth, seventh and eighth inputs of which are connected respectively to the first, second, third and fourth outputs of the third shift register, the first, second and third outputs of the comparator and the third output of the clock generator are respectively the first, second, third and fourth outputs of the block detection and analysis.  3. The device according to claim 1, characterized in that the block for the formation of time intervals is made in the form of parallel connected first, second and third elements AND, the first inputs of which are respectively the first, second and third additional inputs of the node forming interference, and their second inputs are connected among themselves, are connected to the second input of the fifth element And, the first input of the shaper of a single pulse and are the first input of the unit for forming time intervals, the outputs of the first, second and third elements And are connected to the inputs of the corresponding waiting multivibrators, the outputs of which are connected to the corresponding inputs of the first OR element, the output of which is supplied to the first input of the fifth AND element, the output of which is the output of the time interval forming unit, the third input of the fifth AND element is connected to the first input of the second counter and the output of the second OR element the second input of which is connected to the output of the fourth AND element, the second input of the latter is connected to the output of the element NOT, whose input is connected to the tenth input of the shift register and the output the first counter, the first input of which is connected to the first input of the fourth element And, the tenth input of the shift register and is the fourth additional input of the jamming unit, from the first to the eighth inclusive, the inputs of the shift register are connected to the corresponding outputs of the storage register, and the output of the shift register is connected to the first input of the second OR element, the output of the single pulse shaper is connected to the second inputs of the first and second counters and the output of the second counter.

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