SU985786A1 - Random process generator - Google Patents

Description

(5) GENERATOR OF RANDOM PROCESSES

Claims (2)

The invention relates to computing and can be used for modeling systems with regard to the effect of random external disturbances, in the construction of stochastic computing and modeling devices, as well as in the construction of automated test complexes.  A simulator of a random stream of pulses is known, containing a source of Poisson pulse flow, a group of elements AND, a probabilistic (1, K) -polar nik, an element OR, a block of probabilistic decimation.  However, this device does not allow automating the control of the characteristics of the output process in order to specialize the structure of the device to form random processes with the required Cl 3 properties. A generator of random flow pulses is also known, which contains a clock generator, a cyclic shift register, two OR elements, integrator, code-voltage converter and controllable probability element C2.  However, this device does not allow the generation of pulsed signals with random parameters that are subject to specified distribution laws.  The closest to the proposed technical solution is a random pulse process generator containing a series-connected source of reference voltages, first and second code-voltage converters, and a polarity modulator whose output is connected to the output of the simulator, the first pulse generator connected to the counting the input of the pulse counter, serially connected to the second pulse generator, divider. frequency and reversible counter, the first register, the outputs of which are connected to the control inputs of the first code-voltage converter and the field modulator, the second register, the output of which is connected to the control input of the frequency division, interconnected memory block, sensor random numbers, the control unit, and the output of the random number sensor is connected to the setup inputs of the pulse counter and registers to the control inputs of the reversible counter connected to the corresponding outputs of the control unit.  This simulator is designed to generate random, opposite-polar impulses of a triangular shape NW.  However, it does not allow control over a wide range of process parameters and waveform, which limits. its functional capabilities.  The purpose of the invention is to expand the functional capabilities of the generator by forming the required functions of the spectral power density of a random process, managing the structure of the generator to specialize it on the formation of random processes with the required properties and enabling the generator to form two independent random processes.  To achieve this goal, two switches are introduced into the generator, two stochastic converters, whose corresponding outputs are essentially the first and second outputs of the generator, the input of which is connected to the control inputs of the switches, and the second outputs of the stochastic converters are connected respectively to ne ( the evo and the second information inputs of the first switch, the outputs of which are connected to the corresponding inputs of the first memory block, the outputs of which are connected to the group of information inputs of the second comm ator, respectively, the first, second and third outputs of which are connected respectively to the first inputs of the first and second stochastic converters and to the input of a random number sensor, the first, second and third outputs of which are connected respectively to the information input of the second switch and to the second inputs of the first and second hundred hastic converters.  In addition, each stochastic converter contains a pulse generator dat, three memory registers.  two decoders, a counter, a frequency divider, an address counter, a trigger, a multiplier, a code-voltage converter, a modulator and a modulo two, the first input of which is ow. is the first entrance. the converter and connected to the first input of the multiplier, whose output through the converter is the voltage applied to the first input of the modulator, the second input of which is connected to the output of the modulo two, and the output of the modulator is the first output of the converter, the second input of which is connected to the information inputs the first, second and third memory registers, the outputs of which are connected respectively to the installation inputs of the frequency divider and the counter and the second input of the multiplier, which is combined with the second input of the adder and modulo two, a single trigger output is connected to the third multiplier input and to the input of the first pulse generator, the output of which is connected to the counting input of a frequency divider, the OUTPUT of which is connected to the input of the address counter ,.  the output of which is the second output of the converter and is connected via the first decoder to the zero input of the trigger, the zero output of which is connected to the input of the second pulse generator, the output of which is connected to the subtractive input of the counter, the output of which through the second decoder is connected to the installation inputs of the first, second and third registers memory and with a single input tri1-ger.  FIG.  1 shows a block diagram of the proposed device; in fig.  2 scheme of the stochastic converter.  The device contains a block of 1 memory, a sensor 2 random, numbers, the first switch 3, the second switch k, the first stochastic converter 5 the second. stochastic converter; 6.   The first outputs of the stochastic transducers 5 and 6 are the first and second generators, respectively. Ator.  The generator input is connected to the control inputs of the switches 3 and.  The second outputs of the stochastic converters 5 and 6 are connected respectively to the first and second information inputs of the first switch 3.  The outputs of the first switch, 3, are connected to the corresponding inputs of the memory block 1.  The outputs of memory block 1 are connected to a group of information. inputs of the second switch k.  The first, second and third outputs of the second switch are connected respectively to the first inputs of the first stochastic converter 5 and the second stochastic converter bis input of the sensor 2 random numbers.  The first, second and third outputs of sensor 2 are connected respectively to the information input of the second switch 4 and to the second inputs of the first and second stochastic transducers 5 and 6.  Memory block 1 is designed to store codes. determining the type, numerical characteristics of the probability distribution functions of the parameters and the shape of the pulses of the random process being formed.  The random number sensor 2 is designed to form random amplitude, duration, and interval between pulses, subject to the probability distribution functions, the codes of which are stored in memory block 1.  The first switch 3 serves to connect the addresses generated by the first 5 and second 6 stochastic converters and the random number sensor 2 to the corresponding inputs of the memory block 1.  The second switch serves to connect the corresponding outputs of the memory block 1 to the inputs of the stochastic converters 5, 6 and the sensor 2 random numbers in accordance with the specified mode of operation.  The first and second stochastic transducers 5 and 6 are designed to generate streams of pulses with parimeters corresponding to the numbers generated by the random number sensor 2.  Each stochastic converter 5 and 6 contains a first memory register 7, which is designed to receive and store codes corresponding to the current value of the pulse duration; second register 8 memory intended. for receiving and storing codes corresponding to the current value of the interval between pulses; the third memory register 9, which is designed to receive and store codes corresponding to the current pulse amplitude value; the first pulse generator 10, which is intended for 98 66 generating a reference pulse train for subsequent conversion into pulse duration; a frequency divider 11 for converting codes stored in the first register 7 into a time interval; an address counter 12 for generating addresses in which the corresponding waveform ordinates are recorded; a first decoder 13 for generating a control signal for the end of the pulse duration; trigger 1, designed to generate control potentials; a second pulse generator 15, which is intended to form a reference pulse train for the purpose of their subsequent conversion into a time interval between pulses; a subtracting counter 16 for generating time intervals between the impulses; the second decoder 17, which is designed to generate a control signal for the end of the pause between pulses; a multiplier 18 for generating codes proportional to the code stored in the third register 9 and representing the ordinates of the current pulse; The code-voltage converter 19, which is intended to form a process with pulses of the required shape and random values of the pulse duration, the pause between pulses and the pulse amplitude, is not. having one polarity; modulo two adder 20 for forming the polarity sign of the current pulse; a modulator 21 for modulating the field of a random process in accordance with a signal generated by modulo two adder 20.  The first input of cyfwaTopa 20 modulo two is the first input of the converter and is connected to the first input of the multiplier 18.  The output of the multiplier 18 through a code-voltage converter 19 is connected to the first input of the modulator 21, the second input of which is connected to the output of the adder 20 modulo two.  The output of the modulator 21 is the first output of the converter.   the converter input is connected to the information inputs of the first register 7, the second register 8 and the third register 9 whose outputs are connected respectively to the installation inputs of the frequency divider 11, the counter 16 and the second input of the multiplier 18, which is combined with the second input of the modulator two two, the single output trigger And connected to the third input of the multiplier 18. and with the input of the first generator 10 pulses.  Out first. the generator of 10 pulses is connected to the counting input of a frequency divider 11, the output of which is connected to the input of the counter 12 of the address.  The output of the address 12 counter is the output of the converter and is connected via the first decoder 13 to the zero input of the trigger 1.  The zero output of the trigger 1 is connected to the input of the second generator 15 pulses.  The output of the second generator 15 pulses connected to the subtractive input of the counter 16.  The output of counter 16 is connected via the second decoder 17 to the installation inputs of the first register 7 of the second register 8 and the third register 9 of the memory and to the single input three | Hera 1A.  The device can operate in three modes.  The mode of operation is determined by setting the signals at its control input.  In the first mode of operation, the device generates one sequence of pulses of the desired shape with random values of the pulse parameters.  In this case, the accuracy of the reproduction of the laws of the distribution of parameters is n binary bits, and the memory capacity necessary for reproducing one of the laws of the distribution of parameters is equal to 2 control words.  For storing the codes defining the pulse shape, the field of memory is equal to 2 control words.  Thus, for organizing the operation of simulators in the First mode, the memory capacity is 4x2 control words.  In the second mode of operation, the simulator forms two independent streams of pulses of the required shape with random values of parameters.  In this mode, the reproduction accuracy of the law of parameters distribution is binary bits, and the memory capacity necessary for reproducing one law of parameters distribution is P 1-1 t O - - - 4 For storing six laws of process parameters distribution and codes defining two-pulse shapes are needed; the storage capacity is v l 3x2 + --- Control words.  In the third mode of operation, the simulator generates one stream of pulses with random parameters. In this mode, the shape of the current pulse can be selected from the three required forms at random with the required probabilities of the appearance of a pulse of the required form.  The accuracy of reproducing the laws of distribution of process parameters in this case amounts to n2 binary bits of memory capacity, which is necessary for storing the laws of parameters distribution and the law of distribution of the choice of forms, is m2 w control words.  Thus, for organizing the work of the simulator in the third mode, the memory capacity is 1 with 2 control words.  In order to organize the three simulated modes of operation of the simulator, the memory block 1 is divided into four zones with a capacity of m 2 L Each zone has independent address inputs and reading buses.  The device works as follows.  Each cycle of operation of the simulator starts with the fact that for the next pulse of the generated flow a set of values of random parameters (duration, amplitude, interval between pulses) is generated.  The values of the listed process parameters are formed according to specified distribution laws, the codes of which are stored in memory block 1.  Information about the simulator operation mode goes to the control input of the device and to the first inputs of the first 3 and second k switches, the 8 functions of the first switch include connecting the sequence of addresses generated by nepBbiM 5 and the second 6 stochastic converters to the address inputs of the corresponding zone of memory block 1 ti. In the first mode of operation, the first, second and third zones of the memory block 1 are designed to store codes for the distribution of parameters; The fourth zone of the memory unit 1 is intended for storing codes defining the pulse shape of the generated process.  In the second mode of operation, the first and second zones of memory 1 are designed to store codes for the distribution of parameters.  The third and fourth zones of memory block 1 are designed to store codes that determine the shape of pulses generated by the processors. In the third mode of operation, the first zone of memory block 1 is used to store codes for the distribution of parameters.  The second, third and fourth zones are designed to store codes defining the pulse shape of the output process.  The information read from memory block 1 is fed to the input of the second switch C.  Depending on the selected mode of operation of the device, the second switch k connects the outputs of memory block 1 to the required simulator block in accordance with the modes listed below.  In the first mode of operation, the outputs of the first, second and third zones of the memory block 1 are connected to the sensor input 2 of random numbers; the output of the fourth zone of the memory block 1 is connected to the input of the first stochastic converter 5 In the second mode of operation of the device, the outputs of the first and second zones of the block 1 are connected to the sensor input of 2 random numbers; the output of the third zone of memory block 1 is connected to the input of the first stochastic converter 5, and the output of the fourth zone of memory block 1 is connected to the input of the second stochastic converter 6.  In the third mode of operation of the device, the output of the first zone of the memory block 1 is connected to the input of the sensor 2 random numbersJ and the outputs of the second, third and fourth zones of the memory 1 are connected to the input of the first stochastic converter 5 depending on which zone is selected by the sensor 2 random numbers  Codes from the third output of the second switch k are fed to the input of a random number sensor, whose function is to generate streams of random numbers that obey the required distribution law.  The codes from the first output of the sensor 2 random numbers arrive at the third input of the second switch and determine the choice of waveform in the third mode of operation.  Codes from the second and third outputs of the sensor 2 random numbers are received at the first inputs of the first 5 and second 6 stochastic converters.  Stochastic converters 5 and 6 convert codes from the random number sensor 2 into process parameters, and the waveform at the output of stochastic converters 5 and 6 is determined by the codes stored in memory block 1.  Stochastic transducers 5 and 6 generate. the addresses at which the codes defining the waveform are stored in memory block 1, which provides for reading information at a frequency corresponding to the length of the current pulse.  The addresses generated by the stochastic converters 5 and 6 are fed to the second and third inputs of the first switch 3. The stochastic converter works as follows.  The random codes corresponding to the process parameters are generated by a random number sensor 2 and fed to the second input of the function converter.  The formation of the current pulse begins with the writing of codes of random numbers in the first 7 second 8 and Third 9 memory registers, while the trigger H is set to one state.  The enable signal from the unit output of the trigger enters ta control input of the multiplier 18 and to the input of the first generator 10, allowing them to work.  The signal from the zero output trigger li | enters the input of the second generator.  15 and prohibits his work.  The pulse sequence produced by the first generator 10j is fed to the input of the frequency divider 11.  The value of the random code recorded in the first register 7 determines the conversion factor of the frequency divider P.  This provides for each value of the pulse duration the filling of the address counter 12 with the corresponding frequency obtained by dividing the frequency of the pulse process supplied to the input of the frequency divider 11.  The output of the address 12 counter is the second output of the stochastic converter.  Thus, the reading of the codes determining the waveform is carried out at a frequency corresponding to the random code recorded in the first register 7.  The first input of one of the stochastic transducers receives codes that determine the shape of the output signal, with the first digit of the code determining the sign of the waveform arriving at the first input of the adder 20 modulo two.  The rest from the 2nd to the tth, defining the ordinates of the pulse, arrive at the input of the multiplication device.  At the second input of the device, bits from the 2nd to the nth amplitude code recorded in the third register 9 are multiplied.  The first bit of the amplitude code, which determines the polarity of the current pulse, is fed to the second input of the adder 20 addition modulo two.  At the output of the multiplier 18, the ordinate values of the pulse process of the required shape are formed, directly proportional to the amplitude value of the Formed pulse.  In accordance with the codes from the output of the multiplier 18, at the output of the converter 19 of the code-voltage, an analog signal of the required shape is generated with an amplitude corresponding to the code of the amplitude of the pulse being formed.  A polarity modulator 21 changes the polarity of the signal from the output of the code-voltage converter 19 in accordance with the signal produced by the adder circuit 20 modulo two.  Thus, at the output of the modulator 21 of the polarity, which is the first output of the stochastic converter and the output of the device, an analog pulse signal of the desired shape with random values of the amplitude and duration of the pulses is generated.  Upon the completion of the formation of one pulse (when the counter reaches the value 2), the output of the first decoder 13 produces a signal that sets the trigger Il to the zero state.  In this case, a single output of the trigger 1 produces a signal prohibiting the operation of the multiplier 18 and the first generator 10.  At the zero output of the trigger 14, a signal is generated permitting the operation of the second generator 15, and the formation of the time interval between the pulses begins.  Using the second generator 1 5 and the subtracting counter 1b, the conversion of the random code recorded in the second register 8 into the time interval between pulses is organized.  Upon the completion of the formation of the interval (when the subtractive counter 16 reaches the zero state), a signal is produced at the output of the second decoder 17. ending the formation of the interval between. by pulses.  This signal is fed to the control inputs of the first 7, second 8 and third 9 memory registers and to the input of the installation in the trigger unit.  This signal is used to receive new random codes. in the first 7, second 8 and third 9 registers and begins a new cycle of the simulator.  The technical and economic efficiency of the invention is determined by the fact that it provides, in comparison with existing devices, the possibility of forming random external influences, which are pulsed processes with signals of complex shape, as well as sequences of several alternating waveforms, which is important for modeling and testing complex technical systems. ; the possibility of adjusting the type of output process depending on the characteristics of the test or simulated object.  Claim 1.  A random process generator containing a memory block, a random number sensor, characterized in that, in order to expand the functionality of the generator by generating the required spectral density functions, it contains two switches and two stochastic converters, the first outputs of which are respectively the first and second the generator outputs, the input of which is connected to the control inputs of the switches, and the second outputs of the stochastic converters are connected respectively to the first and second information the first switches, the outputs of which are connected to the corresponding inputs of the first memory block, the outputs of which are connected to the group of information inputs of the second switch, respectively, the first, second and third outputs of which are connected respectively to the first inputs of the first and second stochastic converters and to the input of a random sensor numbers, the first, the atom and the third outputs of which are connected 139 respectively with the information input of the second switch and with the second inputs of the first and second stochasts iCal converters.   2. The generator according to claim 1, which means that each stochastic converter contains two pulse generators, three memory registers, two decoders, a counter, a frequency divider, an address counter, a trigger, a multiplier , modulator and modulator, modulator two, the first input of which is the first input of the converter and connected to the first input of the multiplier, the output of which is connected to the first input of the modulator through the converter, the second input of which is connected to the output of the adder modulo two and the modulator output is the first output of the converter, the second input of which is connected to the information inputs of the first, second and third memory registers, the outputs of which are connected respectively to the installation inputs of the frequency divider and the counter and the second input of the multiplier, which is combined with the second rig.1 is the input of a modulo-two adder; a single trigger output is connected to the third multiplier input and to the input of the first pulse generator, the output of which is connected to the counting input of a frequency divider, the output of which is connected to the input of an address counter, the output of which is the second output of the converter and the first decoder is connected via a zero-level trigger input, the zero output of which is connected to the input of the second pulse geyrator, the output of which is connected to the subtractive input of the counter, the output of which is through the second decoder soy dinene with the installation inputs of the first, second and third memory registers and with a single trigger input. Sources of information taken into account in the examination 1. USSR author's certificate number, cl. G 06 F 7/58, 197. 2. Author's certificate of the USSR. If 511679, class H 03 K 3/84, 197A. 3- USSR Author's Certificate No. 517018, cl. G 06 F 7/58, 197 (prototype).