SU1587501A1 - Nonstationary random pulse process generator - Google Patents

Abstract

The invention relates to computing and can be used to create simulation equipment, for solving problems of statistical radio. The purpose of the invention is to expand the class of tasks to be solved due to the possibility of forming packets and packs in the output pulse train. The generator contains a group of seven uniformly distributed random number generators, a group of seven memory blocks, a group of five OR elements, five registers, a multiplication unit, a code-voltage converter, an OR element, a polarity modulator, three frequency dividers, two counters, a memory unit, a trigger, two pulse generators, two decoders, two switches, two sequence duration forming units, a period-interval control unit, two sample number analysis units, and a control unit. 3 hp f-ly, 6 ill.

Description

The invention relates to computer technology and can be used in the creation of simulation equipment, for solving problems of statistical radio, in the construction of automated - test complexes.

The purpose of the invention is to expand the class of tasks to be accomplished by forming packages and, packs, in the output sequence of y-pulses.

In FIG. 1, it is rendered; structural diagram of a non-stationary random pulse process generator; Fig. 2 is a block diagram of the control unit; fig 3 - structural

I

a circuit for forming a duration of sequences; FIG. 4 is a block diagram of a sample number analysis block; FIG. Fig. 5 is a block diagram of a period-interval control block.

The generator contains a group of seven generators, 1 uniformly distributed random numbers, a group of seven memory blocks 2, the first register 3, the multiplication unit 4, the converter 5, the code is voltage, the element OR 6, the modulator 7 polarity, the second register 8, the first frequency divider 9, first counter 10, memory block P, trigger 12, first pulse generator 13

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owls, second frequency divider 14, third register 15, second counter 16 first decoder 17, second decoder 18, second pulse generator 19, third frequency divider 20, fourth register 21, first switch 22, first and second blocks 23 and 24 for forming duration of sequences , the period-interval control unit 25, the first and second blocks 26 and 27 analysis of the number of samples the fifth register 28, the control block 29 the second switch 30 and a group of five elements OR 31.

The control unit 29 contains eleven elements AND 32-42, ten elements OR 43-52, trigger 53 and register 54. The sequence duration forming unit contains two registers 55 and 56, a controlled pulse generator 57, a frequency divider 58 and a counter 59 The sample number analysis block contains a register 60, a counter 61, and two decoders 62 and 63. The period-interval control block contains six flip-flops 64-69 switch 70 and AND 71.

The generator of a non-stationary random pulse process allows generation of pulse flows of a certain shape with a random amplitude and duration, grouped into packets, which, in turn, can be grouped into bundles. The probability characteristics of the following randomly varying characteristics of the process are set separately and independently from each other: the amplitude of the pulses, the duration of the pulses, the period of the pulses (or the interval between pulses), the number and 1 pulses in the packet, the period of the packet (or packages), the number of packages in a pack, the period of the pack (or the interval between packs). In addition, the pulse shape can be specified separately by setting all the ordinates of a pulse on a certain scale, time scales when forming the pulse duration, pulse period (or interval between pulses), packet period (or interval between packets), packet period ( or interval between packs). In addition, it is possible to choose between two modes of operation, when either random periods (pulse periods, packs, packets) measured between the front and back are set.

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mi fronts of the corresponding pulses, or random intervals measured between the falling edge of one pulse and the leading edge of the next one.

The generator works as follows.

Before the generation with the help of the first switch 22 begins, the initial information input to the information input of the first switch 22 is written to various blocks of the generator sequentially. This recording is effected by commands given to the input of the task of operating modes of the specified switch.

The following source information is transmitted and distributed into generator blocks: the code that determines the pulse impulse scale (from output I of the first switch 22 is written to the third register 15); the code defining the packet duration scale (from output 2 of the first switch 22 is input to the time scale setting of the first sequence duration shaping unit 23) the code that determines the pack duration scale (output 3 of the first switch 22 is input to the time scale setting of the second block 24 - shaping the duration of the sequences); the code for setting the starting address (from output 4 of the first switch 22 is fed to the input of the preset of the first counter 10); codes of ordinates, specifying that. or another form of generated pulses (from the output 5 of the first switch 22 is fed to the information input of the memory unit 11); codes of functions that are inverse to the integral functions of the probability distribution of the amplitude of pulses, pulse duration, period (interval) of pulses, number of pulses in a packet, period (interval) of a packet, number of packet, period (interval) of a packet (served output 6 of the first switch 22 to the information inputs of the group 2 memory units, the information on the probability distribution of pulse amplitudes, pulse duration, number of packets in a burst, number of pulses in a burst, burst period (interval), burst period (interval) ( ntervala) pulse is recorded in blocks 2-15 sootvetvenno 22, the memory 27 group)...; code.

defining mode of operation period-. pulse interval, burst, packet (supplied from outputs 7-9 of the first switch .22, respectively, to the first, second and third inputs of the period-interval control unit 25, the logical unit being a unit of the period mode, and logical zero - an indication of the interval mode); the code defining the scale of the period (interval) (supplied from output 10 of the first switch 22 to the information input of the fourth register 21). In the initial state, the trigger 12 and the second counter 16 are reset to the zero state, the control unit 29 is blocked by the Stop signal. The Start signal is reset to the initial state of the first and second blocks 26 and 27 of the sample analysis. At the same time, the Start signal through the elements OR 31, -31 of the group of elements OR 31 starts all seven generators 1 of uniformly distributed random numbers of the group. These generators produce seven equally spaced random numbers that serve as addresses for the corresponding blocks of the 2 -2-J group memory. Under the influence of signals from the output.

Commodity or FP - 315 groups arriving at the readout control inputs of all blocks 2 of the group memory, the information is read from the memory cells defined by the codes on the address inputs of the memory blocks. As a result, a random number appears at the information output of each of the memory blocks 2, -27, subject to the probability distribution, given before the generator starts operating.

These random numbers are distributed as follows; from the output of memory block 2 are sent to the information input of the first register 3, setting a random pulse amplitude, from the output of memory block 2 to the information input of the second register 8, setting a random pulse duration, from the output of memory block 2 input installation of the first block 26 analysis of the number of samples, setting a random number of packets in a pack, from the output of memory block 2 to the installation input of the second block 27 analyzing the number of samples setting a random number of pulses in the packet, from the output of memory block 2 to the reference input

25

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neither the duration of the first block 23 of forming the duration of the sequences, specifying a random period (interval) of a packet, from the output of block 2e of memory to the input of the duration of the second block 24 shaping the duration of the duration; t, qtay, specifying a random period (interval)

10 packs, from the output of memory block 2, to the information input of the fifth register, setting a random period (interval) of the pulse.

At the same time, a signal 15 appears at the output 7 of the control unit 29. By this signal, the trigger 12 is transferred to the unit state, fixing the beginning of the leading edge of the output pulse; the signal from the output 7 of the control unit 29 is also fed to the input of the second block 27 of the analysis of the number of samples, reducing the contents of the counter 61 by one. This indicates that a regular impulse is formed, and the number of impulses included in this packet of pulses, which must be formed further before the completion of the packet, has decreased by one.

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A single signal from the direct output of the trigger 12 is fed to the read control input of the memory unit 11 and j to the start input of the first generator 13 pulses. This generator begins to generate a sequence of clock pulses arriving at the clock input of the second divider I4 clock-40th. The frequency of occurrence of pulses at the output of the second frequency divider 14 is determined by the code contained in the third register 15, affecting the input of setting the division factor of the second frequency divider 14. This determines the time scale of the output pulse duration. The change of the pulse duration is randomly produced using blocks 8-10 as follows: pulses from the output of the second frequency divider 14 are fed to the clock input of the first frequency divider 9. The division factor of this 5 divider is determined by a random number written in the second register 8 and affecting the input of setting the division factor of the first frequency divider 9. Pulses from the output of the lane.

The first frequency divider 9 arrives at the counting input of the first counter 10 by changing its contents, starting with the initial value set at the preset input.

The bit output of the first counter is connected to the address input of the memory block 11. Since there is already a single signal at its read control input, as the codes change, the output input of memory block 11 will produce values defining the pulse shape recorded in memory block 1 before the generator starts. These decisions are fasting. They are fed to one of the inputs of the multiplication unit 4, to the other input of which information is fed from the first register 3, which stores a random number characterizing the pulse amplitude. The result of the multiplication from the output of the block, the multiplication is fed to the converter 5 code - voltage and then to the modulator 7 polarity, in which, depending on the state of the sign bit number in the first register 3, the output voltage from the converter code - voltage or not is changed (in register 3 is a positive number), or inverted (in register 3 is a negative number). As a result, at the output of the modulator 7 of the polarity, which is the generator output, a pulse is formed with a predetermined shape, random amplitude and duration. The pulse shaping ends at the moment when a signal appears at the output of the first decoder 17 configured to a predetermined number ordinate impulse.

When the trigger 12 goes into a single state, the sigpal from its direct output also acts on the fifth input. Block 25 of the period-interval control and the second control input of the second switch 30. If the Packet Period, Packet Period, Pulse Period modes occur, the block 25 period-interval control outputs signals at the first second and third outputs. In this case, the signal from the second output of this block enters the start input of the first block 23 for forming the duration of the sequences, thereby beginning the countdown of the duration of the packet period,

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the signal from the third output of the period-interval control block 25 is supplied to the input of the second block 24 for forming the length of the sequences, thereby beginning the counting of the duration of the pack period. The signal from the first output of the period-interval control unit through the IPI 6 element affects the start input of the second pulse generator 19, as a result of which clock pulses appear at the output of this generator to the clock input of the third frequency divider 20. The division factor is It is the code recorded in the fourth register 21 and specifying the time scale of the period. In turn, according to the signal at the second control input, the second switch 30 analyzes the information received by its first control input in order to find out what information should be transmitted to the output of the second switch: from the output of the current duration or from the output the specified duration of the first 23, or the second 24 generation unit of the duration of the sequences, or from the information output of the fifth register 28. In this embodiment, the output from the output of the fifth register 28, specifies the impu period lsa.

At the time of completion of the formation of the output pulse, when a signal appears at the output of the first decoder 17, this signal resets the trigger 1-2 to the zero state, thus fixing the trailing edge of the output pulse. The resulting single signal from the inverse output of the trigger 12 is fed to the tenth input of the control unit 29, after which, at the first and fourth outputs of the control unit 29, pulses appear, restarting the generators of uniformly distributed random numbers of the group. If the generator operates in the Pulse interval mode, then in this case the second pulse generator 19 is started not from the period-interval control unit 25, but again with a single signal from the inverse output of the trigger 12 via the second input of the element 6. At this, using the second counter 16, will be counted for a duration of 9

The interval is not from the leading edge of the output pulse, as was the case in the Period and Tulse modes, but from the rear of the front edge of the output pulse, which is required for counting the interval between pulses. Both in that and in the other case, the completion of this counting is performed at the moment of zeroing of the second counter 16 (it works to reduce the content when each counting pulse arrives), which is detected by the second decoder 18. The signal that occurs at the output of the second decoder 18 is fed to the reset input the first counter 10, drive it to its original state. At the same time, it arrives at the eleventh input of control unit 29, after which a pulse appears at its seventh output, i.e. starts - repeating the new cycle of generation of the next pulse in the packet.

The demand repetition will take place until the last pulse in the packet is generated. In this case, compared with the described actions, the following differences occur: the code changes at the eighth output of control unit 29, and so to the second counter 16. at the preset input is recorded through the second switch 30, or the output code of the current duration of the first block 23 forming the duration of the grouse sequences (Packet Period mode), or the code from the output of the specified duration of the same block (Packet Interval mode). In addition to Toroj, the signal from the sixth output of control block 29 is fed to the counting input of the first block of analysis of the number of samples, reducing the contents of the counter 61 by one. This indicates that the number of packets that need to be formed further before the completion of the pack has decreased by one.

In the final part of the pulse generation cycle, the control unit 29, along with the signals at the first, fourth and seventh outputs, form control signals at the third and fifth outputs ,; thereby, OR 31, and 314 are used to start the generators of uniformly distributed random numbers 1 and Ij, forming the address codes of blocks 2 and 2; memory groups, as a result of the outputs of these

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In the case of memory blocks, random numbers appear - respectively, the value of the number of pulses in the subsequent packet, inputted to the installation of the second block 27 analyzing the number of samples, and the value of the period (interval) of the next packet, which enter the input of the duration of the first 10 block 23 forming the duration sequences.

When generating the last pulse of the last packet in a packet at the eighth output of control unit 29, a code appears - 5 s, which records the second counter 16 via the second switch 30 or the output value of the current duration of the second block 24 forming the sequence length (Packed period mode) or-value from the output of a given duration of the same block (Packed interval mode). In the final part of the pulse generation cycle, control unit 29 25 generates signals on the first, second, third, fourth and fifth outputs, launching (through the elements of OR 31 groups) all seven generators J of uniformly distributed random numbers of the string, then the block 29 control produces a signal at the seventh output and t, d repeat all the actions that take place during the initial start-up of the generator. A similar operation of the generator continues until the occurrence of the Stop signal, by which it stops functioning.

The control unit 29 is designed 40 and generating control signals based on information from the outputs of the first and second blocks 26 and 27 of the analysis of the number of samples. The control unit 29 operates as follows. Formation of the output signals of this block can be carried out only in the absence of Stop signals and

The start also at the single state of the trigger 53. Conversion to the single state of this trigger in each alternate cycle of the generator is made by the signal from the inverse output of the trigger 12 (at the initial start - by the Stop signal). In the absence of Stop and Start signals and a single state of the flip-flop 53 of the control block 29, a single signal also takes place at the output of the AND 32, allowing a functional

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AND 33-41 logic elements. These elements, in combination with AND 42, OR 44-49 logic elements, form a logic circuit generating signals to the outputs 1-7 of the control unit 29 of the w-sh with certain combinations of signals at its inputs and. providing the described sequence of operation and interaction of individual generator blocks. The trigger 53 is reset to the zero state by a signal from the output of the elements OR 44 when any of the elements OR 44-49 is triggered. The output signals of the elements OR 50-52, as well as the output signals of the elements And 33 and 40, form in register 54 a five-bit position code that determines which source through the second switch 30 the code should be loaded into counter 16: from the register 28, from the register 56, the first 23 or the second 24 block for forming durations of sequences, from the counter 59 of the block 23 or the block 24,

Sequence duration shaping units are designed to form a burst of pulses (first block 23) or bursts of pulses (second block 24) of a certain duration. The first block 23 forming the duration of the sequences works as follows. Before the generator starts its operation, the second output of the first switch 22 inputs a code defining the time scale of the packet duration to the input of the time scale. This code is entered into the first register 55 of block 23, where it is stored for the entire time of the generator. At the initial moment of the formation of the next pack from the output of block 2 of the memory of the group, a random number is received that determines the random duration of the pack. This number is recorded in the second register 56 of block 23, where it is preserved for the duration of the formation of the packet. The signal from the second output of control block 29 supplied to the input of the block 23 is pre-set by the counter 59 of block 23: the code from the second register 56 of block 23 is copied to it. Simultaneously, in the packet period mode, the signal from the second block 25 period-interval management. Controlled generator 57 pulse5

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The block 23 begins to generate a continuous sequence of clock pulses applied to the clock input of the frequency divider 58 of the block 23. At the output of the 58h divider, frequency pulses appear with a frequency determined by the division factor of the frequency divider 58 specified by the code stored in the first register

55 of block 23, thereby setting the time scale of the packet duration. The pulses from the output of the frequency divider 58 are fed to the counting input of the counter, 59, the content of which decreases by one with the arrival of each counting pulse. The bit outputs of the counter 59 of block 23 are the output of the current packet duration,

and the output of the second register 56 is the output of a given packet duration.

The second block 24 forming the duration of the sequences works similarly to the first block 23, In the first register 55 of the block 24 from the third output of the switch 22 is entered the code of the time scale of the duration of the pack, in the second register

56 of block 24, at the beginning of each burst, a random number is recorded coming from block 2g of the memory of the group; the preset of the counter 59 of the block 24 occurs on a signal from the second output of the control block 29, and the signal to the start input of the controlled generator

57 pulses of block 24 in the Bund period mode passes from the third output of the period-interval control block 25. The output of counter 59 of block 24 is the output of the current pack duration, and the output of the second register 56 of block 24 is the output of a predetermined pack duration.

The blocks of analysis of the number of samples are designed to analyze the given and current number of packets (first block 26) or the number of pulses in the packet (second block 27). The first block 26 analyzes the number of readings works as follows. At the initial moment, when the Start signal is given, the counter 61 resets. block 26 to the initial state. Then, at the beginning of the burst formation, a random number from the output of block 2 of the group memory specifying the total number of packets in the burst is recorded in register 60 of block 26. Further on the signal from the second

The EXIT of control unit 29 rewrites the number from register 60 to counter 61j, i.e. the preset of the counter 61. With the arrival of each successive pulse from the sixth output of the control unit 29, the contents of the counter are reduced by one. The first and second decoders 62 and 63 analyze the contents of register 60 and counter 61, respectively, generating the output signals of block 26. The second block 27 analyzes the number of samples works similarly to the first block 26, at the beginning of the formation of each packet in register 60 of block 27 The random number from the output of block 2ij of the memory of the group indicates the number of pulses in this packet, the number is rewritten into counter 61 of block 27 by the signal from the third output of control block 29, and changes in the contents of counter 61 by pulses С seven th output of the control unit 29.

The period-interval control unit 25 operates as follows. Before the generator starts operating, at outputs 7-9 of the first switch 22, triggers 64-66 of block 25 enter a code defining the period-interval operation mode when forming a sequence of pulses, packets and packs. The code from the eighth output of control block 29 is fed to the control input of switch 70 of block 25, determining the transfer to the output of switch 70 of the period-interval characteristic either from trigger 64 (when forming the duration between pulses of one packet), or from trigger 65 (when shaping the packet duration ), or with the trigger 66 (when forming the duration of the pack). At the moment when the flip-flop 12 is switched to one state, the signal from the direct output of this flip-flop arrives at the fifth input of the unit 25, affecting the enable entries of the flip-flop recording 67-69. If trigger 65 is in a single state (sign of a packet period), trigger 68 will also go to a single ssG condition by triggering the first block 23 for forming the length of sequences 23. Similarly, if trigger 66 is in a single state (sign of a pack period), then. in the single state, the trigger 69 passes, executing 587501 14

ow start the second block 24 forming the duration of the sequences. At the same time, if the trigger 67 is in the single state through the AND element 71 of the block 25, and then the OR element 6 starts the second pulse generator 19.

Claims (4)

) 0 claims one . A generator of non-stationary random impulse process, containing a group of three generators of equally-f5 number-distributed random numbers, a group of three memory blocks, first, second, third and fourth registers, multiplication unit, converter code - voltage, polarity modulator 20, first, second and third frequency dividers, first and second counters, first and the second decoder, the trigger, the OR element, the first and second pulse generators, a 25 mt block, and the first output of the first register is connected to the first input of the multiplication unit, the output of which is connected to the information input of the converter code - voltage, output 30 of which connected to the information input m polarizer, the input of which the polarity of the output voltage is connected with the sign bit of the first register, and output 35 is the generator output, the bit output of the second register is connected to the input of the division factor of the first frequency divider, the output of which is connected to the counting the input of the first counter, the bit output of which is connected with the address input of the memory block and the input of the first da coder, the output of the memory block is connected to the second input of the multiplier 45, the output of the first decoder is connected to the input ohm flush reset, the direct output of which is connected to the read control input of the memory unit and the start input of the first pulse generator 0, the output of which is connected to the clock input of the second frequency divider, the input of setting the division factor of which is connected to the bit output of the third register and the output - 5 with a clock input of the first frequency divider, the inverse output of the trigger is connected to the first input of the OR element, whose output is connected to input-1 of the second pulse generator start i The output of which is connected to the clock input of the third frequency divider, the input of setting the division factor of which is connected to the output of the fourth register, and the output to the counting input of the second counter, the output of the second counter is connected to the input of the second decoder whose output is . In order to expand the class of tasks due to the possibility of forming packets and packs in the output pulse train, four generators of uniformly distributed random numbers are additionally added to the group of generators of uniformly distributed random numbers: These are additionally four blocks of memory, two switches, two blocks for forming the duration of sequences, a block for controlling the interval, two blocks for analyzing the number of readings, fifth registration p, a group of OR elements and a control unit, consisting of eleven AND elements, ten OR elements, a trigger and a register, the output of the first AND element of the control unit being connected to the first inputs of the second, third, fourth, fifth, sixth, the seventh, the eighth; the ninth and tenth elements AND the control unit, the output of the first element OR of the control unit is connected to the installation input of the trigger of the control unit, the direct output of which is connected to the input of the first element AND, and the inverse to the first input of the eleventh element AND, the outputs of the second, third, the fourth, fifth, sixth, seventh, eighth, ninth and tenth elements of AND are connected to the inputs of the second OR element of the control unit, the output of which is connected to the reset input of the trigger of the control unit, the outputs of the second, third and fourth elec - And connected to the inputs of the third element of the control module RSHI, the output of which is connected to the first inputs of the fourth, fifth and sixth elements I.PI of the control unit, the outputs of the fifth, sixth and seventh elements are connected respectively to the BTopbiM, the third and fourth inputs of the fourth the OR element of the control unit, the outputs of the first, and eighths sixteen 0 five 0 five 0 five 0 five 0 five The first AND elements are connected to the second and third inputs of the fifth OR element of the control unit, the output of the sixth AND element is connected to the second input of the sixth 1PI element of the control unit, the outputs of the ninth and tenth AND elements are connected to the inputs of the seventh OR element of the control unit, the outputs of the second and eighth elements And are connected to the installation inputs of the first and second bits of the register of the control unit, respectively, the outputs of the seventh and tenth elements of AND are connected to the inputs of the eighth element OR of the control unit, you the strokes of the third, fifth, and eighth elements I are connected to the inputs of the ninth element OR of the control unit, the outputs of the fourth and sixth elements I are connected to the inputs of the tenth element OR of the control unit, the outputs of the eighth, ninth and tenth elements OR of the control unit are connected to the installable the inputs of the third, fourth, and nth bits of the register of the control unit, respectively, the outputs of each of the generators of uniformly distributed random numbers are connected to the address inputs of the corresponding groups; the first control input of the first switch is the input of the generator operating mode, the information input of the first switch is the input of the characteristics of the generated pulse process, the first output of the first switch is connected to the information input of the third register, the second output of the first switch is connected to the input setting the time scale of the first block of the formation of 1W for the length of the sequences, the third output - with the input of setting the time scale of the second block of forming the duration The fourth output - with the input of the preset of the first counter, the fifth output - with the information input of the memory block, the sixth output - with the information inputs of the memory blocks of the group, the seventh, eighth and ninth outputs of the first switch are connected respectively to the first, second and the third inputs of the period-interval control block, the tenth output - with the information input of the fourth register, the outputs of the first, second.  7I58750I the third, fourth, fifth, sixth and seventh memory blocks of the group are connected respectively to the information input of the first register with the information input of the second register, to the installation inputs of the first and second blocks of analysis of the number of samples, to the inputs of the duration of the first and second blocks forming the duration of the sequences, with the information input of the fifth register, the generator stop input is connected to the prohibition input of the second counter, with the first inverse input of the first element I of the control unit and with the first input The first element of the OR control unit, the generator start input is connected to the reset inputs of the first and second samples of the number of samples, the second inverse of the first element AND control unit and the first inputs of the OR group, the output of the first OR element is connected to the trigger the inputs of the first and second generators of uniformly distributed random numbers of the group and with the control inputs for reading the first and second memory blocks of the group, the output of the second OR element of the group is connected to the trigger inputs of three of the third and sixth generators of uniformly distributed random numbers of the group and with the control inputs of reading the third and sixth memory blocks of the group, the output of the third element OR of the group is connected to the trigger input of the fourth generator of uniformly distributed random numbers of the group and with the control input of reading the fourth block the group am, the output of the fourth element W of group is connected to the triggering input of the fifth generator of automatically distributed random numbers of the group and with the control input of reading the fifth memory block -. and the group, the output of the fifth LIE element of the group is connected to the start of the seventh generator of uniformly distributed random numbers of the group and to the read control input of the seventh group memory block, the output of the first sample count local location is connected to the second inputs of the second, third and fourth elements AND board unit and with the first inverse in and out of and with, Q in and out in an anime t5 and in no way in the second 20 block with and in 25 NIN it is counted 30 Dami And blit a block of 35 k at the entrance investment And a block of 40 ka and a second 45 one-third of the house of 50 a unit number of that inverter from the second block 18 the inputs of the fifth, sixth and seventh - elements And control unit, the output of the alarm of the last count of the first block of analysis of the number of samples is connected to the second inverse input of the sixth element And of the control block with the second input of the seventh element And control block, the first inverse, Q input of the ninth element And control unit, the output signal of the last readout of the first block of analysis of the number of readings is connected to the second inverse input of the sixth element t5 AND of the control unit, to the second input of the seventh element And the control unit, The first inverse input of the ninth element AND control unit and the second input of the tenth element AND 20 of the control unit, the output of equality of the number of samples to the unit of the first analysis unit of the number of samples is connected to the third input of the second element AND of the control unit, and the output exceeds 25 NIN of the number of samples of the unit with the third input of the fourth element I of the control unit, the output of the counts of the second unit of analysis of the number of samples is connected to the fourth inputs of the second and fourth elements of the control unit, with the third city of the third and of the seventh control unit I, the second inputs of the fifth and seventh control unit 35, the first inverse inputs of the eighth and tenth, the second inverse input of the ninth control unit, the output of the equality of the number of samples samples connected to the fifth inputs of the second and fourth elements of the control unit / second inverse inputs of the fifth and eighth elements of the control unit, 45 third inputs of the sixth and tenth elements of the control unit, the fourth input of the seventh and the second input of the ninth element AND control unit, the output of the excess of the number of samples of the unit of the second analysis unit of the number of samples is connected to the fourth input of the third element And control unit, the output of the second decoder is connected to the second input of the eleventh element And control unit, inverse the trigger output is connected to the second input of the first OR element of the control unit, the output of the second OR element of the control unit is connected with the second input of the first element OR of the group, the output of the third element OR of the control unit is connected to the second input of the second element of the group III, the inputs of the preparation of the first block of analysis of the number of samples, the first and second forming units, the duration of the sequences, the output of the fourth element OR of the control unit is connected the input of the third element OR group, the input of the second unit of analysis of the number of samples, the output of the fifth element OR of the control unit is connected to the second input of the fifth element OR group, the output is A simple OR element of the control unit is connected to the second input of the fourth element of the Sh1I group, output seven. The control unit OR is connected to the counting input of the first analysis unit, the number of samples, the output of the eleventh control unit I and the control unit is connected to the counting input of the second sample number analysis unit and the trigger setup input, the control controller register output is connected to the first control input of the second switch and the fourth input of the period-interval control block, the direct output of the trigger is connected to the second control input of the second switch and the fifth input of the period-interval control block first the second and third outputs of which are connected respectively to the second input of the OR element, to the start inputs of the first and second sequence duration shaping units; the first, second, third, fourth and fifth information inputs of the second switch are connected to the current duration and a given duration of the first block of formation of the duration of the sequences, the current duration and a specified duration of the second block of the formation of the duration of the sequences, bit output In the fifth register, the output of the second switch is connected to the preset input of the second counter. 2. The generator according to claim 1, characterized in that the block forming the duration of the sequences contains two registers controlled pulse generator, the divider is often five 0 five 0 You and the counter, the information input of the first register is the input of setting the time scale of the block, the information output of the first register is connected to the input of the setting of the dividing factor of the frequency divider, the clock input of which is connected to the output of the controlled pulse generator, the start input of which is the start input of the block, the output of the frequency divider is connected to the counting input of the counter, the pre-enable enable input of which is the block preparation input, and the counter output is the output of the current duration The sequence of the block, the information input of the second register is the input of the set of the duration of the block sequences, and its output is connected to the input of the initial installation of the counter and is the output of the specified duration of the block sequences. 3. Generator pop.1 is different from the fact that the block of analysis of the number of samples contains a register, a counter and two decoders, the information input of the register being the input of the unit, the information output of the register connected to the input of the preset of the counter and the input of the first decoder , the first output of which is the output of the equality of the number of samples to the unit block, the second output of the decoder is the output of exceeding the number of samples of the unit of the block, the reset inputs of the preset resolution and the count input 1 of the counter are By the inputs of the reset, preparation, and block counting, the information output of the counter is connected to the input of the second decoder, the first output of which is the output of the end of the block readings, and the second output is the signal output of the last count of the block. 4. Generator pop. 1, I differ by the fact that the control unit is 0 0 five neither the period-interval contains six triggers switch and ele-. ment Ji, the information inputs of the first, second and third flip-flops are respectively the first, 5 second and third inputs of the block, the direct output of the first trigger is connected to the first information input of the switch, the output of which is connected to the information input of the fourth the trigger input and the control input of the switch is the fourth input of the unit, the forward output of the second trigger is connected to the second information input of the switch and the information input of the fifth trigger, the output of the third trigger is connected to the third information input of the switch and the information input of the sixth trigger, inputs- permission to record info87501 .22 The fourth, fifth and sixth mates are triggers combined with a second entrance. And is the fifth input of the block, the direct output of the fourth flip-flop is connected to the first input of the element AND whose output is the first output of the block, the direct outputs of the fifth and sixth flip-flops are the second and third outputs of the block, respectively. ten g g IfOt zavany mt.eabat nishShT FIG 2