SU1309021A1 - Random process generator - Google Patents

Abstract

The invention relates to computing. The purpose of the invention is the extension of functionality due to the formation of non-stationary random processes. The generator contains a memory block, a random number sensor, the first and second switches, the first and second stochastic converters, the information input unit, the mode register, the decoder. The goal is achieved by introducing new blocks and functional links that implement the principle of software control of the device. The generator has four modes of operation, the mode of operation is determined by the code stored in the mode register. In the first mode, the generator generates two sequences of pulses with randomly distributed parameters in accordance with the required distribution functions. B & In the second mode of operation, two independent streams with random amplitudes and durations are formed. In the third mode, one sequence of pulses of the required shape is formed with random values of pulse parameters. In the fourth mode, a stream of pulses with random parameters is formed. In this mode, the shape of the current pulse can be selected from three forms randomly with the required probabilities of appearance of each form. 1 h, para. f-crystals, 2 tab., 4 ill. i SL

Description

The invention relates to computer technology and can be used to model systems with regard to the influence of random factors, in the construction of stochastic and modeling devices, as well as in the construction of automated test complexes.

The purpose of the invention is to expand the .. functionality of the generator due to the formation of non-stationary random processes, control-time parameters of the generated random pulses.

Fig. 1 shows the scheme of the proposed generator; figure 2 - block diagram of the input information; FIG. 3 is a diagram of a stochastic converter; FIG. 4 is a diagram of a random number sensor.

The random process generator and the information input unit (Figures 1 and 2) contain a random number sensor 1, switches 2-4, memory blocks 5 and 6, memory register 7, mode register 8, decoders 9-14, elements 15-17 delays, triggers 18-21, nine elements AND 22-30, nine elements OR 3139, a pulse counter 40, a pulse generator 41, the first 42 and the second 43 stochastic transducers.

Each stochastic converter (fig. 3) contains a trigger 44, six registers 45-50 of memory, three counters 51-53, an adder 54 modulo two, three switches 55-57, an inverter 58, two converters 59, and 60 voltage code , generator 61 pulses, delay element 62, first 63 and second 64 elements I.

Sensor 1 of random numbers (FIG. 4) contains three elements OR 65-67, six elements AND 68-73, two triggers 74 and 75, a generator of 76 pulses, a memory register 77, a generator of uniformly distributed numbers 78, an adder 79, three switches 80-82, delay element 83, counter 84, two decoder 85 and 86, encoder 87, groups of elements And 88.

The operation of the generator should be considered in relation to its three states; initial loading of information; process generation; correction of a part of information stored in the internal storage device.

The information supplied to the generator determines the distribution law of the parameters, the waveform of the output

five

0

five

0

five

0

five

0

five

process, time parameters of impulses, code of an operation mode. This information has the following structure.

The first code determines the type of command executed by the generator. This may be the initial load command, the command for correcting the information that determines the type, the numerical characteristics of the probability distribution functions of one of the parameters, or the pulse shape of the process being formed; it can also be a command to correct information defining the process time characteristics and mode code

work. one

The following codes define the type and

numerical characteristics of the functions of the distribution, the likelihood of the parameters, and the waveform of the output process. This information is recorded in memory block 5. The latter contains four zones each. of which has its own I / O bus information.

The remaining part of the codes determines the time parameters of the process, the mode of operation of the generator, these codes are stored in the fourth 48 and fifth 49 registers of stochastic converters 42 and 43 and in register 8 of the mode.

The initial loading of information is carried out as follows. A sequence of codes is fed to the input of the initial parameters of a random process. Each incoming symbol contains To information bits and a synchronizing signal. The information bits of the code are sent to the information inputs of the register 7, to the information input of the second. memory unit 6 and the first information inputs of the third switch 4. The synchronization signal is fed to the input of the third delay element 17 and to the first inputs of the fifth 26 and sixth 27 elements I. In the initial state, 20 is in unity. 20, there is a uro-permitting passage of the synchronized signal to the output of the fifth element AND 26. This signal enables the recording of information in the register 7, sets the fourth trigger 21 to one and sets the counter 40 to zero. After a time t equal to the delay signal on the third delay element 17, the third toigger 20 is set to

the third trigger state, the third trigger

zero state. The value of Tj is selected in such a way that the third trigger 20 is set to the zero state by the arrival of subsequent sync signals. Then all subsequent sync signals will be fed to the output of the sixth element And 27.

If the code recorded in register 7 is the original command code

15

20

load, then at the third output of the first transducers 42 and 43, the first descriptor 9, there appears a potential allowing the fourth decoder 12. This same signal goes to the control input of the third switch 4, allowing the output on its output of the codes on the first entrance. The enabling signal from the third output of the first decoder 9 through the third element OR 33 is fed to the first input of the seventh element And 28 and allows it to work. The same signal, having passed through the fourth element OR 34, arrives at the control input of that decoder 13 and allows it to work.

Subsequent sync signals are received through the sixth element AND 27 and the eighth element AND 29 at the input of the fifth element OR 35. In the initial state, the second trigger 19 is in the zero-ZO state, the signal at its forward output inhibits the operation of the generator 41 and the second memory block 6 . The sequence of sync signals through the fifth element OR 35 is fed to the count input 35 of the counter 40, at the output of which a code sequence of addresses is formed.

Codes generated by the counter 40,

Information is stored in memory 5 by means of the first switch 2, whose function is to organize the connection of one of its inputs to the output corresponding to a specific area of memory 5, taking into account the mode of operation and the state of the generator.

When writing information to the first memory block 5, the first switch 2 connects the codes from the input of the task to the initial parameters of the generator process. The recording takes place at the addresses generated by the counter 40. The low bits of the counter determine the address inside the zone, and the zone is selected by decoding the high order bits of the address using the fifth decoder 13.

The information in mode register 8 and in registers 48 and 49 of stochastic transducers is transmitted using the sixth decoder 14,

When writing information to the register memory of the generator on the fifth bus of the fifth decoder 13, a signal appears, which arrives at the control input of the sixth decoder 14, is released to the input of the fifth decoder and solves its operation. The address code, post13, at the output of which information reception permission signals are generated for each zone of memory block 5 and for a register memory located in stochastic converters 42-5 and 43. Thus, a sequence of information codes is generated corresponding to these memory address codes. generator and control signals allowing -5 recording of information. When the counter reaches 40, a value corresponding to the number of codes received at the initial load, the output 4 input to the sixth decoder 14 is frustrated, and its outputs receive signals by which the information is stored in the generator's register memory.

After the necessary information has been recorded in the generator memory, it is in the state of forming a random process.

The principle of forming a random process used in the generator is as follows. Each cycle of the generator begins with the formation of a set of values of random

true decoder 12 generates S parameters (duration, amplitude

with a signal which, having passed through the second element OR 32, confirms that the first state is set to the zero state

18 and second 19 triggers and sets the third trigger 20 to one state. Thus, the generator is ready to receive the next command.

Codes from the output of the third switch 4 are fed to the information inputs of the mode register 8, memory block 5 and to the information inputs of the fourth 48 and fifth 49 stochastic registers

These converters 42 and 43,

Information is stored in memory 5 by means of the first switch 2, whose function is to organize the connection of one of its inputs to the output corresponding to a specific area of memory 5, taking into account the mode of operation and the state of the generator.

When writing information to the first memory block 5, the first switch 2 connects the codes from the input of the task to the initial parameters of the generator process. The recording takes place at the addresses generated by the counter 40. The low bits of the counter determine the address inside the zone, and the zone is selected by decoding the high order bits of the address using the fifth decoder 13.

The information in mode register 8 and in registers 48 and 49 of stochastic transducers is transmitted using the sixth decoder 14,

When writing information to the register memory of the generator, on the fifth bus of the fifth decoder 13 a signal appears, arriving at the control input of the sixth decoder 14, rapping to the input of the sixth decoder 14, is deleted, and on its outputs with the help of which the recording of information into the register memory of the generator is organized.

After the necessary information has been recorded in the generator memory, it is in a state of forming a random process.

The principle of forming a random process used in the generator is as follows. Each cycle of the generator begins with the formation of a set of values of random

signals, intervals between adjacent signals). The values of the process parameters are formed in accordance with

given probability distribution functions; The codes that define these functions are stored in the first block of 5 memory. From the output of the random number sensor 1, the generated parameter values are fed to the inputs of the first 45 second 46 and sixth 50 registers of stochastic transducers.

In the function of stochastic converters, the transformation of incoming random codes and process parameters is initiated. The pulse shape of the process is determined by the codes that are stored in the first memory block 5.

The device has four modes of pulse duration. In this case, the accuracy

bots. The mode of operation is determined by the code stored in mode register 8. In the first mode of operation (mode code 00), the device generates two-:

the sequence of pulses with the case-20 law of the distribution of one of the parameters Nj 2 control words.

parameters distributed in accordance with the required probability distribution functions (amplitude, the duration of the signal bases and the interval between adjacent signals). In this case, the accuracy of the reproduction of parameters is M - 2 binary bits.

The storage capacity required to reproduce a single law of parameter distribution is N ,. 2 M / 4 control words, the first zone of the memory block 5 intended for storing codes defining the laws of probability distribution of parameters for the first process; The second memory zone is intended for storing the ordinate waveforms of the first process. In this mode of operation, the distribution of the zones of the memory block 5 is as follows: the first three zones are intended for storage

25 codes defining the laws of distribution of the likelihood parameters of signals, the fourth memory area is designed to store the ordinate codes of the output process.

30 In the fourth mode of operation, the generator generates a single stream of pulses with random parameters. In this mode, the shape of the current pulse can be selected from three possible forms

j randomly with the required probability of occurrence of each form. The accuracy of the reproduction of the laws of probability distribution is M - 2 binary bits, and the capacity of the memory.

j randomly with the required probabilities of occurrence of each form. The accuracy of the reproduction of the laws of probability distribution is M - 2 binary bits, and the capacity of the memory.

caj the third memory zone is intended for storing codes defining the necessary; 40 is necessary for storing the rac function, the cones of the distribution of the parameters of the second probability limit of one para process; the fourth memory zone is intended for storing codes defining the ordinates of the pulse shape of the second process.

In the second mode of operation (mode code 01), the generator generates two independent streams of random signals, with the amplitudes of the pulses and the duration of their bases being random quantities distributed in accordance with the required probability distribution functions, and the interval

55

N 2M / 4 N meter.

The distribution of the memory zones of block 5 in the fourth mode of operation is as follows: the first 45 zones are designed to store the codes of the four probability distributions; the second, third and fourth zones contain the ordinate codes of the pulse shapes.

between adjacent signals is a random variable evenly distributed. In this mode, the accuracy of reproduction of the probability distribution law of parameters (amplitudes and

The generator operation cycle will be considered from the moment of the formation of the current pulse at the output of the first 42 or second 43 stochastic converters. One of the features of the generator is that the formation of the i-th group of random codes. carried out during the time interval when stochastic transformations

90216

the base duration of the signals of the process is M − 1 binary bits. The capacity of the memory, necessary for reproducing one law g of the probability distribution of parameters, is N2 2 M / 2 control words,

The distribution of zones in memory block 5 in the second mode of operation corresponds to the memory allocation for the first fO mode.

In the third mode of operation (mode code 10), the generator generates one sequence of pulses of the desired shape with random values of the parameter reproduction of the probability functions of the signal parameters equal to M binary signals. The storage capacity required for storing codes. In this mode of operation, the distribution of the zones of the memory block 5 is the following: the first three zones are intended for storage

codes defining the laws of distribution of probabilities of signal parameters; the fourth memory zone is intended for storing the ordinate codes of the output process.

In the fourth mode of operation, the generator generates a single stream of pulses with random parameters. In this mode, the shape of the current pulse can be selected from three possible forms

randomly with the required probabilities of occurrence of each form. The accuracy of the reproduction of the laws of probability distribution is M - 2 binary bits, and the capacity of the memory.

necessary for storing the function of races, the probabilities of probabilities of one para-

40 is required to store the probability distribution function of one para-

„

N 2M / 4 N meter.

The distribution of the memory zones of block 5 in the fourth mode of operation is as follows: the first 45 zones are designed to store the codes of the four probability distributions; the second, third and fourth zones contain the ordinate codes of the pulse shapes.

The generator operation cycle will be considered from the moment of the formation of the current pulse at the output of the first 42 or second 43 stochastic converters. One of the features of the generator is that the formation of the i-th group of random codes. carried out during the time interval when stochastic transformations

designers 42 and 43 form a random pulse signal corresponding to (1-1) -th group of codes,

Thus, with the beginning of the formation of the i-ro pulse at the output of the first element OR of the first 42 or second 43 stochastic transducers, signals are generated that, having passed through the ninth element 39, pos8

In the fourth generator operation mode, the output of the first zone of the memory block 5 is connected to the input of the sensor 1 random numbers, and the outputs of the second, third and fourth zones of the memory block 5 are connected to the input of the first stochastic converter 42, depending on which zone is selected 1 random numbers. Codes with

blunt to the input. Start of sensor 1 of the fourth output of sensor 1 of random tea numbers and initiate regular numbers arrive at the first control

generator cycle. The sensor 1 of random numbers forms a set of values of random parameters, and the number of generated parameter values is variable and depends on the code of the mode of operation of the generator. So, for the first and second modes of operation, the random number sensor 1 generates a sequence of 6 random parameters, 20 for the third — 3, and for the fourth –4.

The function of the random number sensor 1 also includes the generation of addresses where function codes are stored.

The second input of the second switch 3 determines the waveform selection in the fourth mode of operation.

The formation of random numbers with the required probability distribution laws is carried out as follows. Sensor 1 of random numbers implements the conditional probabilities method.

The essence of the method lies in the formation of a random number, and the probability of occurrence of O or 1 in the iM bit is determined depending on what combinations start with the input to the Start of the sensor 1 random numbers and the probability distributions of the required le and units in the previous i-1 parameter in accordance with the mode of the data.

generator work. These addresses from the first cycle of forming a random number of the information output of the sensor 1 of random numbers go to the third input of the first switch 2. The function of the equal signal that comes to the first switch 2 includes the connection to the first input of the first element AND 68. You — If at the given moment the sensor of random numbers processed by the sensor 1 random chi-1 does not form random numbers, the first 42 and the second 43 stochastic codes, then the first trigger 74 has up-to-date converters to address 35dits to zero and a first state,

the inputs of the corresponding zone of block 5 share.

The information read from memory block 5 is fed to the input of the second switch 3 and, depending on the selected generator operation mode, the second switch 3 connects the outputs of memory block 5 to the required block.

element AND 68 is open at the second entrance. Thus, the Start signal is fed to the input of the first flip-flop 74 and sets it to one. The same signal, passing through the first element OR 65, is fed to the input of the write control register 77, and the code 00 ... 01 is written into it, which corresponds to the initial value. In the first and second modes of operation, the first trigger 74, having received in a single soybean the first and third zones of the memory block 5 are connected to the input of the sensor 1 of random numbers, the outputs of the second and fourth zones are connected to the inputs

this, closes the first element AND 68

on the second entrance. Therefore, the occurrence of the Start signal does not make any changes to its operation. However, for one cycle of the first 42 and the second 43 stochastic 50 bots, sensor 1 of random numbers of the developed converters, respectively. a set of random values of parameters for the first 42 and second 43

In the third mode of operation, the codes of the stochastic transducers. In this way, the second and third zones of block 5 are connected in parallel with the second stochastic request to the sensor input 1 of random numbers, the outputs of the fourth zone of the memory block 5 are connected to the input of the first stochastic converter. first trigger 74 allows operation

The 55th random-to-transducer is also satisfied.

eight

In the fourth generator operation mode, the output of the first zone of the memory block 5 is connected to the input of the sensor 1 random numbers, and the outputs of the second, third and fourth zones of the memory block 5 are connected to the input of the first stochastic converter 42, depending on which zone is selected 1 random numbers. Codes with

the fourth output of the sensor 1 random numbers are received on the first control

The second input of the second switch 3 determines the waveform selection in the fourth mode of operation.

The formation of random numbers with the required probability distribution laws is carried out as follows. Sensor 1 of random numbers implements the conditional probabilities method.

The essence of the method lies in the formation of a random number, and the probability of occurrence of O or 1 in the iM bit is determined depending on what combinations start with the input to the Start of the sensor 1 random numbers yn The cycle of forming random numbers of the equalizing signal which arrives at the first input of the first element And 68. If, at a given time, the sensor 1 of random numbers does not generate random codes, then the first trigger 74 is in the zero state and the first,

element AND 68 is open at the second entrance. Thus, the Start signal is fed to the input of the first flip-flop 74 and sets it to one. The same signal, passing through the first element OR 65, is fed to the input of the write control register 77, and the code 00 ... 01 is written into it, which corresponds to the initial value. The first trigger 74, having entered into a single socket, closes the first element AND 68

- stochastic converters. Thus, the request of the second stochastic parameter. Setting the first trigger 74 to one state allows the operation

The 55th random-to-transducer is also satisfied.

ten

91309021

76 pulse generator. In the initial state, the second trigger 75 is in the zero state and the pulses from the output of the generator 76 through the second element And 69 arrive at the synchronization input of the register 77, The input of the shift of the register 77 from the output of the adder 79 receives the signal O or 1 - the result of comparing the codes received from block 5-- of memory to the information input of sensor 1 of random numbers and 78 uniformly distributed numbers produced by the generator 78. Since the output of the generator 76 is connected to an up-equalizing input of the generator 78 of equally distributed numbers, each code appearing at the information input of the sensor 1 of random numbers corresponds to a new uniformly distributed number.

A sign of the end of the formation of a K-bit random number is the presence of a unit in the K + 1 bit of the register 77, which was originally in the low-order bit. Depending on the chosen mode of operation of the generator, the size of the generated random numbers is different and is M-2, M-1 or M binary bits of For

counter 84 im-state 3

ten

The outputs of register 77 are connected to the second information inputs of the first switch 80 and arrive at its output if the mode code is not code 01 and the pulses are not in or 6.

The single state of the second flip-flop 75 opens the third element AND 70 through one of the inputs. Then a pulse from the output of the generator 76 appears at the output of the third element AND 70. This signal, having passed through the first element OR 65, sets the register 77 to the initial state.

Since in the initial state the pulse counter 84 is in the zero state, then the first output of the second decoder 86 has a signal that opens the first circuit

25

a group of elements 88 by one of the inputs, the second input of which receives a signal from the output of the third element 70. Thus, a random number code is formed at the output of sensor 1 of random numbers, and at the corresponding output is a tracking signal. The signal from the output of the third element And 70 also goes to the direct output

And 71

determining when the formation of the fourth element AND 71, which sends a random number, is used covered in the event that the mode code is the second switch 81, the information is not code 01 and the counter 84 which has information received from M-1 , M, M + 1 register bits 77. The sensor mode setting input 1 35 random numbers are connected to the control input of the second switch 81, the output of which contains information about the state of one of the register 77 bits connected to the input. mode 00 or 11 (first or fourth re Clamps operation), then the output of the second switch 81 receives information about M-1 discharge register.

40

If there are code 01 on the control inputs of the switch 81 (second mode of operation), the output of the register de M is received at its output; if the switch inputs 81 of the code 81 of the code 10 (third mode of operation), the output of the register’s information is received +1 register 77.

45

is in the state 2 or 5. From the output of the fourth element And 71, the signal enters the input of the second trigger 75 and sets it to the zero (initial) state.

The signal from the output of the third element And 70, having passed through the delay element 83, is fed to the counting input of the pulse counter 84 and increases its state by one. When forming the next number, the tracking signal appears at the output of the next And 88 group circuit.

In the same way the formation of subsequent random numbers.

The exception is the second mode of operation of the generator (code 01), since in this mode in each cycle of the sensor 1 of random numbers four numbers are generated in accordance with the required distribution law for occurrence in the required bit, and two numbers are formed in register 77 units of the second trigger 75 - generator of 78 uniformly distributed random numbers. This operation is implemented as follows. When forming the second random number

50

is set to one, prohibiting the further arrival of pulses at the input of the shift control.

0

021

0

counter 84 im-state 3

ten

The outputs of register 77 are connected to the second information inputs of the first switch 80 and arrive at its output if the mode code is not code 01 and the pulses are not in or 6.

The single state of the second flip-flop 75 opens the third element AND 70 through one of the inputs. Then a pulse from the output of the generator 76 appears at the output of the third element AND 70. This signal, having passed through the first element OR 65, sets the register 77 to the initial state.

Since in the initial state the pulse counter 84 is in the zero state, then the first output of the second decoder 86 has a signal that opens the first circuit

five

a group of elements 88 by one of the inputs, the second input of which receives a signal from the output of the third element 70. Thus, a random number code is formed at the output of sensor 1 of random numbers, and at the corresponding output is a tracking signal. The signal from the output of the third element And 70 also goes to the direct output

And 71

 the fourth element AND 71, which is open if the mode code is not code 01 and the counter 84 is not 35

the pulse counter 84 is in the second state; From the second output of the second decoder 86, the signal arrives at the input of the second element IL 66.

fO

15

The output of the second element OR 66 is the connection of the 5 cycles of operation of the sensor 1 random number to the second input of the fifth element I 72, the first input of which receives the enabling signal in the case when the mode code is 01. Thus, the fourth element AND 71 is closed inverse input. But the end of the formation of the second number at the output of the third element AND 70 appears a signal that does not arrive at the input of the second trigger 75, and it remains in a single state. With a certain delay, the same signal through the delay element 83 is fed to the input of the counter 84 and brings it to the next state. Then, a signal appears at the output of the second 20 decoder 86, which, having passed through the third element OR 67, arrives at the second input of the sixth element AND 73, which is open at the first input if mode code 01 is set. The output signal of the sixth element And, 73 arrives at the control inputs of the first switch 80, the first information inputs of which receive the codes generated by the generator 78 of uniformly distributed numbers. Thus, with mode code 01 and enabling

25

villages should be formed six numbers. When the counter 84 reaches state 6, a signal appears on the seventh output of the decoder, which, having passed to the output of the third switch 82, sets the counter 84 and the first trigger 74 to the zero state.

If mode code 10 is set, then at the output of the third switch 82, a signal appears when the counter 84 reaches state 4, and with mode code 11, the signal at the output of the third switch 82 appears when the counter 84 reaches state 5.

The function of the random number sensor 1 also includes the procedure of forming the sequence of addresses for accessing to the memory block 5. These functions are performed by the encoder 87. Since the generator can operate in various modes, the memory areas in which the codes of the laws of probability distribution of parameters are stored are different for each mode.

Table 1 shows the memory addresses by which the address is used during the formation of random numbers.

In table 1, the x symbol

are marked

In table 1, the x symbol

are marked

the signal at the third output of the second de, and the addresses formed at the output of the register-encoder 86 at the output of the first com- "35" -, -,

Mutator 80 is a uniformly distributed number.

77. The high-order bits of the address M + 2 and M + 1 determine the zone number of the memory block 5. Subsequent bits are determined by the number of the generated

77. The high-order bits of the address M + 2 and M + 1 determine the zone number of memory block 5. Subsequent bits are determined by the number of the generated

Since the second trigger 75 is the remaining random number and the exit code in one state, the next register is 77. The codes (bits from the 1st general signal produced by generator-2), formed at the output of the register 77, are given on the output of the encoder 8 unchanged.

rum 76 will also pass to the output of the third element And 70. This signal goes to the output of the third element of the groups, 45

M-2) formed at the output of the register 77 are fed to the output of the encoder 8 without changes.

Convert Senior Bit

JMOryT be implemented according

from tab. 2

i

For the implementation of the scheme, a permanent memory can be used.

yy elements And 88 and at the exit of the fourth

of the element And 71, which is open by

inverse input, because the state

counter 84 has changed. Similarly

organized formation at the exit

sensor 1 of the random numbers of the next device (ROM), and in this case

evenly distributed number, the address of the ROM input is received

the second will be the sixth in the general sequence;

random codes.

The end of the cycle of the sensor 1 random numbers is organized at 55

input code, and at this address is written the code to which the address should be converted.

Address codes from the first information sensor 1 random numbers are fed to the third information input of the first switch 2, which is the help of the third switch 82, to the information inputs of which are connected the outputs of the second decoder 86,

and the control inputs of the generator receive the operating mode code. .

If the mode code is set. Generator 00 or 01, then

O

five

5 cycles of operation of the sensor 1 random number 0 0

five

villages should be formed six numbers. When the counter 84 reaches state 6, a signal appears at the seventh output of the decoder, which, having passed to the output of the third switch 82, sets it to the zero state. counter 84 and first trigger 74.

If mode code 10 is set, then at the output of the third switch 82 a signal appears when the counter 84 reaches state 4, and with mode code 11, the signal at the output of the third switch 82 appears when the counter 84 reaches state 5.

The function of the random number sensor 1 also includes the procedure of forming the sequence of addresses for accessing to the memory block 5. These functions are performed by encoder 87. Because the gene is. Since a rator can operate in different modes, the memory areas in which the codes of the laws of probability distribution of parameters are stored are different for each mode.

Table 1 shows the memory addresses by which the address is used during the formation of random numbers.

kla work sensor 1 random chi

In table 1, the x symbol

are marked

addresses formed at the exit register- "" -, -, / -, "" "". "

77. The high-order bits of the address M + 2 and M + 1 determine the zone number of the memory block 5. Subsequent bits are determined by the number of the generated

random number and code at the output of the register 77. Codes (bits from the 1st to

random number and code at the output of the register 77. Codes (bits from the 1st to

M-2), formed at the output of register 77, are output unchanged to the output of encoder 87.

Convert Senior Bit

JMOryT be implemented according

from tab. 2

i

For the implementation of the scheme, a permanent memory can be used.

input code, and at this address is written the code to which the address should be converted.

Address codes from the first information sensor 1 random numbers are fed to the third information input of the first switch 2, which is

They connect them to the address input of the corresponding memory zone 5. Information read from memory block 5 is fed to the input of sensor 1

random numbers through the second switch 3. To the second control input of switch 3, a code is received that determines the mode of operation of the generator.

Codes from the second and third outputs of the sensor 1 random numbers are fed to the second inputs of the first 42 and second 43 stochastic converters. The stochastic converters 42 and 43 convert codes from the random number sensor 1 to the process parameters, and the waveform at the output of the stochastic converters 42 and 43 is determined by the codes stored in block 5

memory Stochastic transforms-20 memory, information in which records.

They generate addresses that store the codes defining the waveform in block 5 of memory, which ensures that information is read at a frequency corresponding to the duration of the current pulse. The addresses generated by the stochastic converters 42 and 43 are fed to the first and second inputs of the first switch 2. In addition, the stochastic converters 42 and 43 form the control signals for the beginning and end of the pulse. The End of Pulse signals are generated at the outputs of the second And 64 elements of the stochastic transducers 42 and 43 and are fed to the first input of the First Element 22 and the first direct input of the And 23 element. Signals The beginning of the pulse

The unit state of the trigger 44 corresponds to the formation time of the duration of the current pulse of the output process. The permissive signal from the single output of the trigger 44 is supplied to the control input of the first converter 59 code - voltage and to the control inputs of the second 56 and third switches, while the outputs of the first switches 56 and 57 are assigned to the outputs of the first And 63 elements The stochastic transducers receive information about the status of the fourths 42 and 43 and arrive at the inputs of the first 48 and fifth 49 registers of the corresponding element OR 39. In addition, the signal of the beginning of the pulse of the first stochastic transducer 42 is personal. A fourth register 48 contains a code defining a range of variation of the pulse duration. C code

blunt to the third control input of the second switch 3.

Stochastic converters 42 and 43 are identical and operate as follows. Random codes corresponding to the process parameters are generated by a random number sensor 1 and recorded in the first 45, second 46 and sixth 50 registers. The fourth 48 and fifth 49 registers store codes that determine the timing of the output process.

Consider the formation of a stream of pulse signals from the moment of occurrence

to

j

902114

signal The beginning of the pulse, which appears at the output of the first element And 63 at the moment when the signal from the output of the second counter 52 converts the trigger 44 into one state. Passing through the delay element 62, the signal goes to the second input of the AND 63 element, the output of which contains the enable signal from the direct output of the trigger 44. The signal from the output of the first And 63 element goes to the control input of the third register 47. by rewriting information into it -. The maths from the sixth register 50. The same signal goes to the second control inputs of the second 56 and third 57 switches. The specific feature of these switches is that they have an internal register

15

25

when the signal arrives at the second control input of the switch. At the end of the signal the beginning of the impulse stochastic transform-ik

The wave generates a current pulse with random parameters, and information about the parameters of the next pulse can be entered in the first 45, second 46, and sixth 50 registers.

The unit state of the trigger 44 corresponds to the formation time of the duration of the current pulse of the output process. The permissive signal from the single output of the trigger 44 is supplied to the control input of the first converter 59 code - voltage and to the control inputs of the second 56 and third switches, while the output of the switches 56 and 57 of post 40 receives information about the fourth 48 and the fifth 49 registers correspond to 40 information about the state of the fourth 48 and the fifth 49 registers of the corresponding

stately. A fourth register 48 contains a code defining a range of variation of the pulse duration. C code

45 output register through the second switch 56 is supplied to the installation inputs of the first counter 51, on the counting input of which receives the clock sequence from the generator 61 and 50 pulses. Thus, at the output of the first pulse counter 51, a sequence of pulses is formed with a frequency inversely proportional to the code determining the range of variation 55 of the pulse duration.

I

The code sequence from the output of the first subtractive counter 51 is fed to the counting input of the third

which receives information from the output of the third switch 57. In the single state of flip-flop 44, information is received corresponding to the value of the current pulse duration. Thus, at the output of the third counter 53 a clock sequence is formed, providing for each value of the pulse width And 64, the second input of the co-pulse (when the second counter 52 of state 2 reaches) at the transfer output of the second counter 52 produces a signal that, acting on the counting input of the trigger 44, translates it into the opposite state. The same signal, passing through the delay element 62, is also fed to the input of the second counter 52, with the corresponding frequency obtained by dividing the frequency of the pulse process fed to the input of the third counter 53.

The codes defining the pulse shape come from the output of the second switch 3, with the first bit of the code defining the sign of the pulse shape:

arrives at the first input of the adder 542059 code - voltage, forcibly

modulo two. The remaining bits are set to zero at its output.

defining ordinates of the impulse, pos-level. Direct output signal

blunt to the second input of the first pre-flip-flop 44 is supplied to the control code of the shaper 59 code - voltage. On

the inputs of switches 56 and 57. At the same time, the codes defining the time parameters of the intervals between pulses and the value of the current interval are sent to the specified switches, using the first 51 and third 53 subtractive counters, the filling speed of the second counter 52 is proportional and the current value of the interval between pulses.

the first input of the first converter code - voltage as a reference voltage receives a signal from the output of the second converter 60 code - voltage. The signal at the output of the second converter 60 is a code-voltage determined by bits, starting with the second, the code recorded in the third register 47. The first bit of the third register 47 is fed to the second input

adder 54 modulo two. So about- 35 When the second counter reaches 52

value 2 at its carry output

at one time, the output of the second converter 60 is a voltage-voltage signal that is proportional to the code. amplitudes of the current pulse. In accordance with the codes supplied to 40 the second input of the first converter 59, the code is a voltage, a signal of the required shape is generated at its output and with an amplitude corresponding to the code of the amplitude of the generated pulse. S

a signal is produced which, arriving at the counting input of the trigger 44, translates it into a single state. The same signal, passed through delay element 62 and the first element AND 63, is converted into a pulse beginning signal, and the cycle of forming a random pulse repeats.

During the current pulse generation time, the sensor 1 random numbers generate new parameter values that are written to the first switch 55 and the inverter 58 changes the polarity of the signal from the output of the first converter 59 code - voltage in accordance with the signal generated by adder 54 to module two. Thus, at the output of the first switch 55, which is the first output

of the entire device, the analog-random numbers are formed that did not exceed the long pulse signal of the required length of the shortest pulse. We have random values of amplitude and pulse duration.

- out 45, second 46 and sixth 50 registers, so the next pulse has different parameter values. To synchronize the operation of the device, it is necessary that the group formation time

Of these considerations, oscillator frequencies 61 and 76 are selected.

The second element 64, the second input of a co-pulse (when the second counter 52 reaches state 2), at the transfer output of the second counter 52 produces a signal which, arriving at the counting input of the trigger 44, transfers it to the opposite state. The same signal, passing through the delay element 62, arrives at the input of the second one at this moment, the enabling signal from the inverse output of the trigger 44. At the output of the second element 64, the signal the end of the pulse starts and the interval between pulses begins to form. from the direct output of the trigger 44 is fed to the control input of the first converter

trigger 44 enters the control

the inputs of switches 56 and 57. At the same time, the codes defining the time parameters of the intervals between pulses and the value of the current interval are sent to the specified switches. and the current value of the interval between pulses.

a signal is generated which, arriving at the counting input of the trigger 44, translates it into a single state. The same signal, having passed through the delay element 62 and the first element 63, is converted into the signal of the beginning of a pulse, and the cycle of forming a random pulse is repeated.

During the time of formation of the current pulse, the sensor 1 of random numbers generated new parameter values, which are recorded in

 random numbers did not exceed the length of the shortest pulse. Of

 45, second 46 and sixth 50 registers, so the next pulse has different parameter values. To synchronize the operation of the device, it is necessary that the group formation time

random numbers did not exceed the length of the shortest pulse. Of

Of these considerations, oscillator frequencies 61 and 76 are selected.

17130902

Read codes defining. The pulse form of the output sequence of the iz-block 5 memory is implemented using the first commutator 2.5.

The flow of information from the memory block 5 to the inputs of the stochastic transducers 42 and 43 is organized by the second switch 3 as follows. In the first and second modes of generator operation, information read from the second zone of memory block 5 is sent to the first output of the second switch, and information 15 is received from the fourth zone of memory block 5 to the second output of the second switch 3.

In the third and fourth modes of operation of the generator, only one process is formed, and the second stochastic converter 43 is not used. 20

In the fourth mode of operation of the generator, information about the shape of the output signal is read simultaneously from the three zones of the memory block 5. The functions of the second switch 3 also include the selection of the required waveform depending on the random code generated by the sensor 1 of random numbers.

The days of the formation of a non-stationary process, represented as a piece-30-stationary process, are sufficient at the required time t; , defining the end of the i-ro interval of stationarity, to write down in the generator memory a new packing information, the nature of the information may be different: partial.

To change the time parameters of the process being formed, it is necessary to change the codes stored in the fourth 48 and fifth 49 registers of stochastic converters 42 and 43,

To change the shape of the output signal, it is necessary to change the information 45 in the required area of the first memory block 5, taking into account the mode of operation of the generator.

To change the law of distribution of parameters (or one parameter) 50, it is necessary to change the information in the required area of memory block 5, taking into account the mode of operation of the generator.

Correction of a part of information is carried out at those times when the block required for rewriting does not participate in the formation of the output process. Considering that Sun, up1 8

Equal information in the generator is stored in two types of memory (memory block 5 and register memory), for. Correction of a part of the information uses two commands: correction of the main memory and correction of the register memory.

The rewriting of information is as follows. Let the generator be in process formation mode. Then the third trigger 20 is in the single state and the device is ready to execute the exchange command; The first code arriving at the generator input is the command code and is recorded in register 7. The synchronization signal of the first code, passed through the fifth element AND 26, sets the fourth trigger 21 to the zero state and resets the counter 40 to zero.

After receiving the first code, the third trigger 20 goes to the zero state, and all subsequent clock signals arrive at the output of the sixth And 27 element. If the code recorded in register 7 is the code of one of the correction commands, then the first or second outputs of the first decoder 9 a signal appears which, having passed through the third element OR 33, arrives at the first input of the seventh element AND 28. After receiving the command code, the quarter trigger 21 is in the one state and the seventh element 28 is open at the second input. The enabling signal from the output of the third element OR 33 through the seventh element And 28 and the seventh element OR 37 is fed to the first input of the eighth element And 29, allowing its operation.

Thus, the sequence of synchronizing signals from the output of the sixth element AND 27 enters the input of the eighth element AND 29 and, passing through the fifth element OR 35, enters the counting input of the counter 40. The output of the counter 40 is connected to the address inputs of the second memory block 6. In this way, the information entered at the input of the initial parameters of the generator process is recorded in the second memory block 6,

In the initial state, the first trig. The ger 18 and second trigger 19 are in the zero state. The inhibit signal from the direct output of the second trigger 19 is fed to the second input of the fourth element OR 34, the first input of which also receives the inhibit signal from the third output of the first decoder 9. At the output of the fourth element OR 34 there is a signal that prevents the fifth decoder from working. 13, and no control signals are generated at its output. If, at the output of the first decoder 13, there are no expectations, when the information is recorded in the buffer memory (second memory block 6), and the address of the beginning of the zone to which the information is overwritten is prepared. In addition, the generator is disconnected from an external source of information. The moment of the beginning of the rewriting of information is determined from the following considerations. From the description of the work stochastic

equaling signals, the recording of the information transducers 42 and 43 of the sensor days into memory block 5 and the generator registers does not occur.

Depending on the correction command being executed, the operation of the second or third decoder is allowed. When the counter reaches 40 the value corresponding to the required number of input characters (the capacity of the zone of the memory block 5 or the number of registers), a signal appears at the output of the second 10 or third 11 decoders, which passes to the output of the sixth element OR 36. This signal indicates the end exchange operations with an external device and performs the following operations.

The end of exchange signal from the output of the sixth element OR 36 sets the fourth trigger 21 to zero. the state, with all the tracking signal signals appearing at the generator input being blocked. In this way, the memory of the generator is protected from unnecessary information.

random numbers can be seen that the device memory is accessed only during the formation of the output pulse. During formation

15 pauses the mark pulse does not occur in the device memory. Therefore, the signals of the end of the pulse 20, which are generated at the outputs of the second elements 64 and the first 42 and second 43 stochastic transducers, are used as the signals determining the beginning of the rewriting of information.

Choosing when to start rewriting

25 is carried out as follows. In all modes of operation of the device, the information in the first and second zones of the memory block 5 refers to the first process being generated. Therefore, when recording

30 of the information in the first or second memory zones, the instant of the start of recording is determined by the signal produced by the first stochastic transducer 42. If 00 zones are used.

The signal of the end of the exchange from the output of the neck is 35 U then the highest bit of the zone number

that element OR 36 is also fed to the first input of the fourth element And 25 and to the input of the first element 15. delay, while the delay of the first element 15 of the delay is selected so that the signal at its output on the wils after it ends at the input. Thereafter, the first trigger 18 is set to one. The signal received at the first input of the fourth element And 25, is present as a prohibiting signal.

The exchange termination signal from the output of the sixth element OR 36 is fed to the installation input of the counter 40, the information inputs of the counter 40 receive a code defining the starting address of the zone of change of information or the starting address of the register memory. Thus, after generating a signal at the output of the sixth element OR 36, the generator goes into the standby state when the information is recorded in the buffer memory (second memory block 6), and the start address of the zone into which the information is overwritten is prepared. In addition, the generator is disconnected from an external source of information. The moment of the beginning of the rewriting of information is determined from the following considerations. From the description of the operation of stochastic converters 42 and 43 of the random number sensor, it can be seen that the device memory is accessed only during the formation of the output pulse. During formation

15 pauses the mark pulse does not occur in the device memory. Therefore, as the signals determining the instant of the beginning of the rewriting of information, signals are used End of pulse, which are produced at the outputs of the second elements 64 and the first 42 and second 43 stochastic transducers.

Choosing when to start rewriting

5 is carried out as follows. In all modes of operation of the device, the information in the first and second zones of the memory block 5 refers to the first process being generated. Therefore, when recording

0 of the information in the first or second memory zone, the start time of the recording is determined by the signal produced by the first stochastic transducer 42. If 00 zones are used

defines membership in the first two zones. The information about the highest rank of the zone is fed to the inverse input of the eighth element OR 38 and at its output a signal is formed that opens the first element And 22 through one of the inputs. The second input of the first element And 22 receives a signal from the first stochastic transducer 42. The control signal passes through the first element And 22, through the first element OR 31 enters its input. If the information is recorded in the third or fourth memory zone, then

depending on the mode of operation of the generator, it may refer to the first or second process.

The highest bit of the mode code goes to one of the inputs of the ninth element And 30. If the third (10) or fourth (11) mode of operation is implemented, then the ninth element of And 30 will be opened on one of the inputs. On the second

the input of the ninth element And 30 receives information about the state of the most significant bit of the memory zone number. If the state of the high bit of the zone number is one, then at the output of the ninth element AND 30 the signal that passed through the eighth element OR 38 resolves to the first element AND 22 is output. Thus, the signal from the output of the first stochastic converter goes to the output of the first element IL-31.

If the mode code is 00 or 01, then the most significant bit of the mode code, entering the inverse input of the first element And 22, allows it to work. The first direct input of the second element And 23 Receives information about the highest bit of the memory zone number and, if it is single, then the second element And 29 is open at the direct second input. Then the control signal from the output of the second stochastic converter 43 is fed to the output of the second

and at the exit of the first ele

element and 23 ment or 31.

If the recorded information relates to the register memory, then the zone number is conventionally assigned the value 100, i.e. the control of the start of the recording occurs in the same way as the recording in the first or second zones of the memory block 5.

As follows from the description of the operation of the stochastic transducers 42 or 43, the access to the register memory occurs only at the time of arrival of the signal. The beginning of the pulse. Since the time intervals / the end of the pulse and the recording of information in the register are small compared with the time of formation of the signal, the probability of their superposition is small. Therefore, we can assume that recording the information on the signal End of Pulse, absorbed by the first stochastic converter 42, does not affect the continuity of the second stochastic converter 43.

and to the inputs of the decoders 10 and 14. At the same time, the control inputs of the second memory block 6 receive a signal from the output of the second trigger 19 permitting the reading of information. Codes from the output of the second memory block 6 are received through the third one-to-one switch 4 to the information inputs of the generator memory devices. Thus, signals are generated by which information is recorded in the required memory area of the generator.

When counter 40 reaches the required value, the output of the second 10 and third 11 decoders generates a signal that, having passed through the sixth element OR 36, confirms the zero state of the fourth trigger 21 and, after passing through the quarters, the AND 25 element and the second element OR 32 sets the second trigger 19 to zero state, and the third trigger

20 - in the unit. The same signal, having passed through the second element 16 of the delay, sets the first trigger 18 to the zero state. The delay time of the second delay element 16 is chosen greater than time 2, for

45 holding the first element 15 of the delay. This ensures stable operation of the first trigger 1B. Setting the zero state to the zero state 19 prohibits the operation of the generator 41 and

thirty

35

40

Thus, the signal from the output of the decoder 13. Thus.

the generator is back to its original state and is ready to execute the following commands.

Claims (2)

the first element OR 31 is fed to the input of the sixth element OR 36, at the second output of which there is a high level, since the trigger 18 is in the unit state. Signal 55 The claims of the invention from the output of the third element And 24 are set- 1. The random process generator pours the second trigger 19 into one containing a random number sensor, a state. The enable signal is the first and second switches, and ten five 15 20 . from the direct output of the second trigger 19, passed to the output of the fourth element OR 34, permits the operation of the fifth decoder. 13, at the exit of which the tire will be excited, corresponding to the zone of corrected information. Allow signal from the output of the second trigger 19 is supplied to the control input of the generator 41. A pulse sequence from the output of the generator 41 is fed through the fifth element OR 35 to the counter input of the counter 40. At the output of the counter 40, a sequence of addresses is received that goes to the address inputs of the memory block 5, to the address inputs of the second block 6 memory and to the inputs of the decoders 10 and 14. At the same time, the control inputs of the second memory block 6 receive a signal from the output of the second trigger 19, which allows reading the information. Codes from the output of the second memory block 6 are received through the third one-to-one switch 4 to the information inputs of the generator memory devices. Thus, signals are generated by which information is recorded in the required memory area of the generator. When counter 40 reaches the required value, the output of the second 10 and third 11 decoders produces a signal that, having passed through the sixth element OR 36, confirms the zero state of the fourth trigger 21 and, after passing through the fourth element AND 25 and the second element OR 32, sets the second trigger 19 to zero state, and the third trigger 20 - in the unit. The same signal, having passed through the second element 16 of the delay, sets the first trigger 18 to the zero state. The delay time of the second delay element 16 is chosen to be longer than time 2, 45 of the holder of the first delay element 15. This ensures stable operation of the first trigger 1B. Installation in the zero state of the second trigger 19 prohibits the operation of the generator 41 and p 25 thirty 35 40 the generator is back to its original state and is ready to execute the following commands. Claims 1. Random process generator comprising a random number sensor, first and second switches, and 2313 The first, second, third and fourth outputs of the first switch are connected to the same address inputs of the first memory block, the first, second, third and fourth outputs of which are connected to the information inputs of the second switch of the same name, the first output of which is connected to the input of setting the parameters of a random number sensor pulse , the first and second stochastic converters, each of which contains a trigger, three memory registers, the first and second counters, modulo two, the first switch, invert The first code converter, the pulse generator, the output of which is connected to the counting input of the first counter, the output of the first bit of the third memory register, is connected to the first input of the modulo two, the output of which is connected to the control input of the first switch, the first information the input of which is connected to the output of the inverter, the input of which is connected to the second information input of the first switch and connected to the output of the first converter code - voltage, the outputs of the first switches of the first and second steel stochastically converters are respectively outputs of the first and second random generator process, characterized u and with the fact that, with the aim of expanding the 35 and second stochastic transformation neither the functionality due to the formation of non-stationary processes, a mode register, six decoders, three delay elements, four triggers, nine AND elements, nine OR elements, memory register, pulse counter, second memory block, switch, generator pulses, the first and second stochastic converters contain the second and third switches, the fourth, fifth, sixth memory register, the second converter code - voltage, delay element, the first and second And elements, the third counter, and in House stochastic inverter output of the fourth register memory is connected to a first data input of the second switch, a second information input connected to an output of a fifth memory register, a first control input of the second switch connected to the first 24 50 five 0 the control input of the third switch, with the forward output of the trigger and with the first input of the first element I, the output of which is connected to the second control inputs of the second and third switches and the recording input of the third memory register, the output of the second switch connected to the information input of the first counter, output the overflow of which is connected to the counting input of the third counter, the overflow output of which is connected to the counting input of the second counter, the informational input of the third counter is connected to the output of the third commutator and the overflow output of the second counter is connected to the counting trigger input and through the delay element is connected to the second inputs of the first and second And elements, the outputs of the first and second memory registers are connected respectively to the first and second information inputs of the third switch, the output of the sixth memory register is connected with an input (the third-register memory input input, the discharge outputs of which, except for the first discharge, are connected to the input of the second converter, the code is the voltage whose output is connected to the first information Zion input of the first transducer code- voltage control input of which is connected to a direct output of the flip-flop, the outputs of the first and second elements 40  . -five 0 sensors are connected respectively to the first input of the first element AND and the first direct input of the second element AND, the output of which is connected to the first input of the first OR element, the output of which is connected to the first input of the third AND element, the second input of which is connected to the first input of the fourth element AND direct output of the first trigger, the unit and zero inputs of which are connected to the outputs of the first and second delay elements, respectively, the output of the third element And is connected to the single input of the second trigger, zero input to costly connected to the input of the second delay element, to the output of the second OR element and to the single input of the third trigger, the zero input of which is connected to the output of the third delay element, whose input is connected to the first inputs of the fifth and sixth AND elements and is the input 2513 synchronization of the generator, the direct output of the third trigger is connected to the second input of the fifth element I, the output of which is connected to the input of the register of the memory register, the information input of which is connected to the information input of the second memory unit, to the first information input of the third switch and is the job input the initial parameters of random processes of the generator, the output of the fourth and fifth bits of the memory register are connected to the inputs of the first decoder, the first and second outputs of which -. connected to the same inputs the other element OR, the outputs of the first the decoder is connected to the control the inputs of the second, third and fourth decoders respectively as well to the control input of the third commutation input of the counter, the output of the detector and to the first input of the fourth element of the AND is connected to the direct with the direct output of the fourth trigger, the inverse output of the third trigger is connected to the second input of the sixth element AND, the output of which is connected to the first input of the eighth element And, in the second input of which is connected to the output of the seventh element OR, the output of the eighth element And is connected to the second input of the fifth element OR, the second input of the first element SH1I is connected to the output of the first element AND, the second input of which is connected to the output of the eighth element OR, the inverse input of which is connected to the input of the ninth. AND element and the second direct input of the second element AND, and connected to the output of the third bit of the memory register, the outputs of the first, second and third bits of which are connected to the information element OR, the output of which is connected to the control input of the fifth decryptor-torus, the information input of which is connected to the information inputs of the second, third and fourth decoders, the counter output and the address input of the second memory block, the Read-write input of which is connected to the forward output of the second trigger, to the second input of the fourth IL element And to the input Starting the pulse generator 5 whose output is connected to the first input of the fifth element OR, the output of which is connected to the counting input of the counter, the zero input of which is connected to the single input of the fourth trigger and to the output of the fifth element And, zero fourth input25 the input of the eighth element OR, the output of the second memory block is connected to the second information input of the third switch, the output of which is connected to the information input of the mode register, the information input of the first memory block and connected to the information inputs of the fourth and fifth registers of memory (each stochastic converter , the output of the second counters of the first and second stochastic transducers are connected to the first and second information 35 inputs of the first switch, respectively, the third information input of which is connected to the first information output of the random number sensor, the second and third information the first trigger is connected to the input of the first outputs of which is connected to the information delay element, with the installation input of the counter, the second input of the fourth AND element, the output of which is connected to the first input of the second OR element, the second input of which is connected to the output of the fourth decrypt; and the third decoders are connected respectively with the left and second inputs of the sixth the first, second and sixth registers of the memory of the first and second stochastic converters, respectively, the fourth information output of the random sensor numbers connected to the first control input of the second switch, the second control input of which is connected to the output of the first element And the first element OR, the output of which is connected to the stochastic converter, is pegged to the installation input of the counter, va and the second group of bit outputs the third output of the first decoder is connected to the first input of the seventh element OR, the second input of which is of the second switch, except for the outputs of the first bit of each group, connected to the second information connected to the output of the seventh element And, 55 inputs of the first converters, the first input of which is connected to the output - the voltage of each stochastic course of the third element OR, The second one is the converter, and the outputs of the first input of the seventh element I are connected to the bits in the first and second group 26 50 15 with the direct output of the fourth trigger, the inverse output of the third trigger is connected to the second input of the sixth element AND, the output of which is connected to the first input of the eighth element And, in the second input of which is connected to the output of the seventh element OR, the output of the eighth element And is connected to the second input of the fifth element OR, the second input of the first element SH1I is connected to the output of the first element AND, the second input of which is connected to the output of the eighth element OR, the inverse input of which is connected to the input of the ninth. element And the second direct input of the second element And and connected to the output of the third bit of the memory register, the outputs of the first, second and third bits of which are connected to the information the input of the eighth element OR, the output of the second memory block is connected to the second information input of the third switch, the output of which is connected to the information input of the mode register, the information input of the first memory block and connected to the information inputs of the fourth and fifth memory registers (of each stochastic converter, the output of the second counters of the first and second stochastic transducers are connected to the first and second information the inputs of the first switch, respectively, the third information input of which is connected to the first information output of the random number sensor, the second and third information the first, second and sixth registers of the memory of the first and second stochastic converters, respectively, the fourth information output of the random sensor numbers connected to the first control input of the second switch, the second control input of which is connected to the output of the first element And the first 27 1 the second switch is connected to the second inputs of adders modulo two of each stochastic converter, the counter output is connected to the fourth information input of the first switch and the information input of the sixth decoder, the first bit output of which is connected to the input of the record of the mode register, the outputs of the second and third bits of the sixth decoder connected respectively to the inputs of the fourth and fifth memory registers of the first stochastic converter, the fourth and fifth bit outputs of the sixth encoder inputs connected respectively to recording the fourth and fifth registers of the second memory stochastic transducer, said fifth output decoder connected to the first control input of the first switch to the control input of the sixth decoder and is connected to the input Read-write the first block pulses, the output of which is connected to the first inputs of the second and third elements I and to the input Poll generator of uniformly distributed numbers, the output of the second element AND connected to the synchronization input of the memory register, the output of the third element AND connected to the second input of the first element OR, to the first inputs of the elements And the group and is connected to the input of the delay element and to the direct input of the fourth element AND, the output of the first, element OR is connected to the input of the initial setup of the memory register, the second inputs of the second and third elements AND Keys to forward and inverse outputs of the second flip-flop, a first input of the adder is a data input of a random number, the second input of the adder connected to the output of the generator and uniformly distributed numbers from the first information input of the first switch, the adder output is connected to the input memory, the output of the register register of the shift of the memory register, the output of the register 30 check to the second control input of the first switch, the second control input of the second switch and connected to the input of the mode setting of the random number sensor; the output of the higher bit of the mode register is connected to the second input of the ninth And element and the inverted input of the second And element, the outputs of the first element And the first and second stochastic converters are connected to the first and second inputs of the ninth element OR, the output of which is connected to the Start input of the random number sensor. 2. Pop-up generator 1, characterized in that the random number sensor comprises three OR elements, six AND elements, two triggers, a pulse generator, a memory register, a generator of uniformly distributed random numbers, an adder, three switches, a delay element, a counter,, two decoder, encoder, group The memory is connected to the second information input of the first switch, the outputs of the four most significant bits of the memory register are connected to the first group of inputs of the encoder and connected to the corresponding bit inputs of the second switch, the first and second control inputs of the second switch are connected respectively to the first switch - the first and second control inputs of the first decoder, with the first and second control inputs of the encoder, with the first and second control inputs of the third switch and are the input of the sensor mode setting tea numbers, the output of the second switch is connected to the single input of the second flip-flop, the zero input of which is connected to the output of the fourth element And, the output of the delay element is connected to the counting input of the counter, the output of which is connected to the input of the second decoder, and the second, third . 45 And elements, the first input of the first ele - 50 fourth, fifth and sixth outputs of the second decoder are connected to the second inputs of the same elements of the And group and to the corresponding information inputs of the third switch, the second and fifth outputs of the second decoder are connected to the inputs of the second element OR, the third and the sixth codes of the decoder are connected to the corresponding The I input is the sensor start input, the second input of the first element i. . connected to the inverse output of the first trigger; the output of the first element I is connected to the first input of the first element 55 OR and to the single input of the first trigger, the direct output of which is connected to the input of the generator start 28 50 O pulses, the output of which is connected to the first inputs of the second and third elements I and to the input Poll generator of uniformly distributed numbers, the output of the second element AND connected to the synchronization input of the memory register, the output of the third element AND connected to the second input of the first element OR, to the first inputs of the elements And the group and connected to the entrance of the Ele. delay point and with the direct input of the fourth element AND, the output of the first, element OR is connected to the input of the initial setup of the memory register, the second inputs of the second and third elements AND are connected to the inverse and direct outputs of the second trigger, the first input of the adder is the information input of the sensor random numbers, the second input of the adder is connected to the output of the generator of uniformly distributed numbers and with the first information input of the first switch, the output of the adder is connected to the input The memory is connected to the second information input of the first switch, the outputs of the four higher bits of the memory register are connected to the first group of inputs of the encoder and connected to the corresponding bit inputs of the second switch, the first and second control inputs of the second switch are connected respectively to the first and the second control inputs of the first decoder, with the first and second control inputs of the encoder, with the first and second control inputs of the third switch and are the input of the sensor mode setting case the output of the second switch is connected to the single input of the second trigger, the zero input of which is connected to the output of the fourth element And, the output of the delay element is connected to the counting input of the counter, the output of which is connected to the input of the second decoder, the second second, third . 29130902130 the inputs of the third element OR, the output of the torus is the first information of the first decoder connected to the first output of the random number sensor, the output inputs of the fifth and sixth elements the stroke of the first switch and the outputs of the i-th AND, the second input of the fifth element AND soe And the groups (where, 3,5.,.) Are dinene with the output of the second element OR, 5 are the second information output of the fifth element AND connected to the house of the random number sensor, the output is the inverse input of the fourth element of the first switch with the outputs j- Oh And, the second input of the sixth element And ale The groups AND (where, 5.6.,.) is connected to the output of the third element is the third information input, OR, the output of the sixth element AND connect the random number sensor, it is not the first and second controllers. the output of the first switch and the outputs of the first switch, the output of the fourth element And the group of the third switch connected to the input, are the fourth information of the zeroing of the counter and to the zero zero output of the sensor to the input of the first trigger, the output of the cipher-i 5 chinzh numbers Table 1 31 1309021 32 Table 2  Z pl / z i z Compiled by And „Stolv moat Editor N.Tupitsa Tehred V.Kadar Proofreader L, Pshshpenko Order 1799/41 Circulation 673 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Project, 4