SU1274129A1 - Generator of quasi-poisson pulse arrival - Google Patents

Abstract

The invention relates to a pulse technique. The purpose of the invention is to increase the reproduction accuracy of the quasi-Poisson impulse stream. To achieve this goal, the device additionally introduces the second and third delay elements 6 and 13, the second storage device (memory), 7, register 8, the second AND-NOT element 12. The device also contains pulse generator 1, generator of 2 pseudo-random uniformly distributed numbers, charger 3, block 4 comparisons, delay element 5, digital-analog converter 9, counter 10, AND-NOT element 11, one-shot 14 and control key 15. The device boosts ochnost reproducing kvaeipuassonovskogo IMC S-pulse stream with specified characteristics, and -. intensity trace (A Vani and amplitude distribution u 1 yl 4ib hO with.

Description

The invention relates to a pulse technique.

The aim of the invention is to increase the accuracy of reproduction of the characteristics of the generated stream.

The drawing shows a functional diagram of a generator of a quasi-Poisson pulse flow.

distribution groups of outputs corresponding to a memory which is connected • The quasi-Poisson pulse flow generator contains 1 pulse generator, 2 pseudorandom uniform numbers generator, the outputs of the first of which are connected to the input inputs of the first device 3, the yen outputs with the corresponding inputs of the first group of inputs of the comparison unit 4, the first delay element 5 , the second delay element 6, serially connected the second storage device 7, register 8, digital-to-analog Converter 9, counter 10, the first element AND 11, the second AND-NOT element 12, connected in series with the third delay element 13, a single-shot 14 and a controlled key 15, the second input of which is connected to the output of the digital-analog converter 9. The output of the pulse generator I is connected to the input of the counter 10, the output of which is connected through the first delay element with the input of the first AND-NOT 11 element, the output of which is connected to the input of the third delay element 13 and the synchronization input of the register 8. The input of the second storage device 7 is connected to the output of the second AND-NOT 12 element, the first input of which is single with the output of the second delay element 6, the input of which is connected to the output of the pulse generator 1 and the input of the generator 2 of pseudorandom uniformly distributed numbers, whose outputs of the first group of outputs are connected to the corresponding inputs of the first group of inputs of the second? memory device 7, the inputs of the second group of inputs of which are connected to the corresponding outputs of the fourth group of outputs of the generator 2 of pseudorandom uniformly distributed numbers, the outputs of the third group of outputs of which are connected to the 'corresponding inputs of the second group of inputs of the unit 4 of comparison, the output of which is connected to the second input of the second element INE 12 The outputs of the second group of outputs of the generator 2 of pseudo-random uniformly distributed numbers are connected to the corresponding inputs of the group of inputs of the first element AND-NOT 11.

Generator 2 of pseudorandom uniformly distributed numbers is made with a scheme for eliminating a forbidden state.

The generator of the quasi-Poisson pulse flow operates as follows.

The pulses from the generator 1 pulses supplied to the input of the generator 2 of pseudorandom uniformly distributed numbers, carry out the formation in the last sequence of pseudorandom uniformly distributed numbers. The values of the numbers received on the buses of the first group of outputs of the generator 2 pseudorandom uniformly distributed numbers to the inputs of the first storage device 3, determine the address of the numbers CS of the last, which are fed to the inputs of the comparison unit 4, comparing these numbers with numbers B ₍ · from the third group of outputs of the generator 2 uniformly distributed pseudo-random numbers. When 0, ·> Β ·, the potential of a logical unit appears at the output of the comparison unit 4. Simultaneously, the number on the buses of the first group of outputs of the pseudo-random generator 2 is uniformly distributed numbers goes to the inputs of the first group of inputs' (information) of the second storage device 7. The pulse delayed by the second delay element 6 for the duration of the transients 6 from the pulse generator 1 is fed to the first input of the second AND-NOT 12 element, the output of which at Cj> B · it is formed by it • a pulse that records the number from the information inputs of the second storage device 7 into its cell, the address of which is determined by the content received at the inputs of the second group of inputs (address) of the second storage device 7 and outputs the generator ¹ outputs the fourth group 2 uniformly distributed pseudo-random numbers.

If the condition C -> B; failed, then the second storage device 7 will be in the Read mode and the number will be read from it at the corresponding address generated by the generator 2 of pseudorandom uniformly distributed numbers. In the second storage device 7, an array of numbers with a predetermined distribution law is recorded and it performs the functions of a buffer memory into which numbers distributed according to a predetermined law enter, read in the absence of condition C jB. .

The pulses from the pulse generator 1 are fed to the input of the counter 10, the division coefficient of which sets the intensity of the quasi-Poisson pulse flow generated by the device. The pulse from the output of the counter 10 through the first delay element 5 is fed to the input of the first AND-NOT 11 element, the output of which is a negative pulse in the presence of logical units at all the inputs of its input group. This pulse writes the number from the second memory device 7 to the register 8, from the outputs of which it goes to the inputs of the digital-to-analog converter 9. The same pulse, delayed by the third delay element 13, triggers the one-shot 14. The pulse generated by the one-shot 14 goes to the first input of the controlled key 15 , which provides a signal from the output of the digital-to-analog converter 9 to the output of the device. The intensity η of the output pulses of the device is defined as where f ₀ is the frequency of the pulses at the output of the pulse generator 1;

g is the division ratio of the counter 10;

S - bit depth of the second group of outputs of the generator 2 pseudo-random uniformly distributed numbers.

The amplitude distribution of the output pulses of the device is determined by the distribution of the array of pseudorandom numbers in the second storage device 7.

The bit depths of the third, first and second groups of outputs of the generator of 2 pseudo-random uniformly distributed numbers determine respectively the discreteness of the amplitude of the pulses generated by the device, the discreteness of the representation of the reproduced amplitude distribution law and the degree of difference between the generated stream and the Poisson stream, the width of the fourth group of outputs - the degree of approximation of the pseudorandom amplitude distribution to random by the criterion of a series of identical numbers.

Claims (1)

The invention relates to a pulse technique. The aim of the invention is to improve the accuracy of reproduction of the characteristics of the formed stream. The drawing shows the functional diagram of the generator quasi-Poisson pulse flow. The quasi-Poisson pulsed flow generator contains a pulse generator 1, a generator of 2 pseudo-random uniformly distributed numbers, the outputs of the first group of outputs of which are connected to the corresponding inputs of the first storage device 3, the outputs of which are connected to the corresponding inputs of the first group of inputs of the comparison unit 4, the first delay element 5, the second element 6 delays, serially connected second storage device 7, register 8, digital-to-analogue converter 9, counter 10, first AND-H element 11 ,, second IS-NO 12, serially connected third delay element 13, one-shot 14 and control key 15, the second input of which is connected to the output of the digital-to-analogue conversion of body 9. The output of the generator I pulses is connected to the input of counter 10, the output of which is through the first the delay element is connected to the input of the first AND 11 element 11, the output of which is connected to the input of the third delay element I3 and the register 8 synchronization input of the second memory device. Va 7 is connected to the output of the second IS-NO 12 element, the first input of which is connected to the output of the second delay element 6, the input of which is connected to the output of the pulse generator 1 and the generator 2 input of pseudorandom uniformly distributed numbers, the outputs of the first group of outputs of which are connected with the corresponding inputs of the first group of inputs of the second storage device 7, the inputs of the second group of inputs of which are connected to the corresponding outputs of the fourth group of outputs of the generator 2 pseudorandom uniformly distributed letters the villages, the outputs of the third group of outputs of which are connected to the corresponding inputs of the second group of inputs of the comparator unit 4, the output of which is connected to the second input of the second EE element 12. The outputs of the second group, the generator outputs 2 of pseudorandom uniformly distributed numbers are connected to the corresponding inputs of the group of inputs of the first element I -NOT 11. Generator 2 pseudo-random, evenly distributed numbers are complete with a forbidden state elimination scheme. The generator of quasi-Poisson pulsed flow works as follows. The pulses from the generator 1 of the pulses, which are fed to the input of the generator 2 of pseudo-random uniformly distributed numbers, form in the last sequence pseudo-randomly uniformly distributed numbers. The values of the numbers arriving at the buses of the first group of outputs of the generator 2 pseudo-random uniformly distributed numbers at the inputs of the first storage device 3 determine the address of the numbers C of the latter, which are fed to the inputs of the comparison unit 4, comparing these numbers with the third group of outputs of the generator 2 of pseudo-random evenly distributed numbers. When C ,. at the output of comparator unit 4, the potential of a logical unit appears. At the same time, the number of outputs of the generator 2 of pseudo-random evenly distributed numbers is fed to the inputs of the first group of inputs (informational) of the second storage device 7. The pulse delayed by the second element 6 of the delay element from the generator 1 of the pulses is fed to the first input of the second element I -HE 12, on which vpr a pulse is generated, recording the number from the information inputs of the second storage device 7 into its cell, whose address is determined to contain name, coming to the inputs of the second group of inputs (address) of the second storage device 7 from the outputs of the fourth group of outputs of the generator 2 pseudorandom uniformly distributed numbers. If the condition is not fulfilled, the second storage device 7 will be in Read mode and a number will be read from it at the corresponding address generated by the generator 2 of pseudorandom uniformly distributed numbers. In the second storage device 7, an array of numbers is written with a given distribution law and it performs the functions a buffer memory into which the numbers distributed according to a given law are received, read in the absence of the C-sB condition. , 1 The pulses from the pulse generator 1 are fed to the input of the counter 10, the division factor of which sets the intensity of the quasi-Poisson pulse flow generated by the device. The pulse from the output of the counter 10 through the first delay element 5 is fed to the input of the first element NAND 11, at the output of which a negative pulse is formed when there are logical units on all inputs of the group of its inputs. This pulse records the number from the second storage device 7 to the register 8, from the outputs of which it is fed to the inputs of the digital-to-analog converter 9. This same pulse, delayed by the third delay element 13, triggers the one-shot 14. The pulse formed by the one-shot 14 is fed to the first input of the controlled key 15, which provides a connection signal from the output of the digital-to-analog converter 9 to the output of the device. The intensity n of the subsequent output pulses of the device are defined as pl.2.2, g where f & is the frequency of the pulses at the output of the pulse generator 1; g is the division factor of the counter 10; S is the size of the second group of outputs of the generator 2 of pseudorandom uniformly distributed numbers. The amplitude distribution of the output pulses of the device is determined by the distribution of the array of pseudo-random numbers in the second storage device 7. The discreteness of the amplitude of the pulses generated by the device, the discreteness of the reproducible amplitude distribution law and the degree of the reproduced amplitude distribution law and the degree of the reproduced amplitude distribution law and the degree difference of the generated flow from the Poisson flow, the fourth group of output s - the degree of approximation to the pseudo-random amplitude distribution by the criterion of the same series of numbers. An inventive generator of a quasi-Poisson pulsed flow, comprising a pulse generator, a pseudo-randomly: evenly distributed number generator, the outputs of the first group of outputs of which are connected to the corresponding inputs of the first storage device, the outputs of which are connected to the corresponding inputs of the first group of inputs of the comparator, digital-analogue converter, counter, the first delay element, the output of which is connected to the input of the first NAND element, the one-shot, the output of which is connected to the first the control key input, the pulse generator output is connected to the counter input, the inputs of the input group of the first AND-NO element are connected to the inputs of the second group of outputs of the pseudo-randomly distributed numbers generator, the outputs of the third group of outputs are connected to the corresponding inputs of the second group of inputs of the comparator, different By the fact that, in order to increase the accuracy of reproduction of the characteristics of the flow being formed, the second delay element, the second NAND element, the second memory device are introduced into it The real estate, the register, the third delay element, the output of which is connected to the one-shot input, the second input of the controlled key is connected to the output of the digital-to-analog converter, the inputs of which are connected to the corresponding outputs of the register, the inputs of which are connected to the corresponding outputs of the second storage device, the inputs of the first group of inputs of which are connected with the corresponding outputs of the first group of outputs of the generator of pseudorandom uniformly distributed numbers, the outputs of the fourth group of outputs of which are connected s with the corresponding inputs of the second group of inputs of the second storage device, the input (which is connected to the output of the second AND-NOT element, the first input of KOTopOi -1274129. .at . connected to the output of the second element of the input of the second element, and NOT, the output : delays whose input is connected to the counter connected to the input of the first the input of the pseudorandom element of the delay element, the output of the first electrically uniformly distributed numbers of the I-NOT is connected to the input of the synchronous output of the pulse generator, the output 5 of the register base and the input of the third the comparison unit is connected to the second delay element.