RU2421770C1 - Walsh function random generator - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: device has two counters, a group of AND elements, two half adders, a flip flop, four AND elements, two OR elements, two registers, three random pulse sequence generators, a bidirectional counter and a memory element.

EFFECT: broader functional capabilities owing to successive generation of Walsh functions with a random number, random pause between functions, with random phase shift of the generated Walsh functions and with random polarisation of Walsh functions in direct or inverted form.

1 dwg, 1 tbl

Description

The invention relates to automation and computer technology and can be used in stochastic functional converters, stochastic computing devices for probabilistic modeling and stochastic data processing, as well as in communication systems and networks, including those using LTE technology.

A known Walsh function generator containing a counter, a register, a group of AND elements, an adder modulo two, a trigger, a first and second AND element, a first OR element, a random pulse generator, a reversible counter, a third and fourth AND element and a second OR element (see copyright certificate for the invention N 1117622, CL G06F 1 / 02.1983).

A disadvantage of the known generator is limited functionality, since it provides the generation of Walsh functions with random numbers and with random pauses between sequentially generated functions, but is not able to carry out a random phase shift of the generated Walsh functions.

Closest to the technical nature of the present invention is a stochastic generator of Walsh functions, containing a first counter, first register, a group of AND elements, an adder modulo two, a trigger, four AND elements, two OR elements, a first shaper of a random pulse sequence, a reversible counter, and a second a counter, a second generator of a random sequence of pulses and a second register, the counting input of the first counter connected to the clock input of the generator, the outputs of the same bits first The register is connected to the corresponding inputs of the corresponding elements AND groups, the outputs of which are connected to the inputs of the adder modulo two, the output of the first element OR is connected to the counting input of the trigger, the inverse output of which and the output of the adder modulo two are connected to the corresponding inputs of the first element And, the output of which is the output of the generator, the clock input of which is connected to the input of the first shaper of a random pulse sequence, the output of the first shaper of a random pulse sequence with is single with the first inputs of the second and third elements And, the second input of the second element And is connected to the first input of the fourth element And is connected to the direct output of the trigger, the second input of the third element And is connected to the inverse output of the trigger, the second input of the fourth element And is connected to the clock input of the generator , the output of the second element And is connected to the serial input of the first register, the outputs of the third and fourth elements And are connected respectively to the summing and subtracting inputs of the reversible counter, the output of which bitwise connected to the inputs of the second OR element, the output of which is connected to the first input of the first OR element, the counting input of the second counter is connected to the clock input of the generator, the zeroing input of the second counter is connected to the output of the second OR element, the overflow output of the second counter is connected to the second input of the first OR element , the input of the second driver of the random pulse train is connected to the clock input of the generator, the output of the second driver of the random pulse train is connected to the input of the second register, the outputs of which are connected to the information inputs of the first counter, the recording permission input of which is connected to the output of the second OR element (see copyright certificate for the invention N 1777131 from 01/28/91, cl. G06F 1/025, published 11/23/92 in bulletin No. 43, author - Turko Sergey Aleksandrovich).

However, this generator has limited functionality, since in this stochastic generator of Walsh functions, which generates Walsh functions with random numbers, with random pauses between sequentially generated functions and with a random phase shift of the generated functions, there is no possibility of generating Walsh functions with random polarity, in direct or inverted form. However, in the problems of probabilistic modeling and data processing, in stochastic devices, it becomes necessary to generate Walsh functions with random numbers, with random pauses between sequentially generated functions, with a random phase shift of the generated functions and with a random polarity of Walsh functions, in direct or inverted form. In the proposed stochastic generator of Walsh functions, this drawback is eliminated.

The aim of the invention is to expand the functionality by providing the generation of Walsh functions with random numbers, with random pauses between sequentially generated functions, with a random phase shift of the generated functions and with a random polarity of Walsh functions, in direct or inverted form.

This goal is achieved by the fact that in the well-known stochastic generator of Walsh functions, containing the first counter, first register, group of AND elements, the first adder modulo two, trigger, four AND elements, two OR elements, the first shaper of a random pulse sequence, a reverse counter, the second a counter, a second generator of a random sequence of pulses and a second register, the counting input of the first counter connected to the clock input of the generator, the outputs of the same bits of the first register connected to the corresponding inputs of the corresponding elements AND groups, the outputs of which are connected to the inputs of the first adder modulo two, the output of the first element OR is connected to the counting input of the trigger, the inverse output of which is connected to the first input of the first element And, the output of which is the output of the generator, the clock input of which is connected to the input of the first shaper of a random pulse sequence, the output of the first shaper of a random pulse sequence is connected to the first inputs of the second and third elements AND , the second input of the second element And is connected to the first input of the fourth element And and connected to the direct output of the trigger, the second input of the third element And is connected to the inverse output of the trigger, the second input of the fourth element And is connected to the clock input of the generator, the output of the second element And is connected to the serial input the first register, the outputs of the third and fourth elements AND are connected respectively to the summing and subtracting inputs of the reversible counter, the output of which is bitwise connected to the inputs of the second element OR, output One of which is connected to the first input of the first OR element, the counting input of the second counter is connected to the clock input of the generator, the zeroing input of the second counter is connected to the output of the second OR element, the overflow output of the second counter is connected to the second input of the first OR element, the input of the second random pulse generator is connected to the clock input of the generator, the output of the second shaper of a random pulse sequence is connected to the serial input of the second register, the outputs of which are connected are connected to the information inputs of the first counter, the recording permission input of which is connected to the output of the second OR element, the third random pulse train driver, the memory element and the second adder are modulo two, and the clock input of the generator is connected to the input of the third random pulse train, the output of which is connected with the information input of the memory element, the recording permission input of which is connected to the output of the second OR element, the output of the memory element is connected to the first input the second adder modulo two, the second input of which is connected to the output of the first adder modulo two, the output of the second adder modulo two is connected to the second input of the first element I.

The drawing shows a structural diagram of a stochastic generator of Walsh functions.

The stochastic generator of Walsh functions contains the first counter 1, a group of elements And 2, an adder 3 modulo two, trigger 4, elements And 5 and 6, element OR 7, first register 8, the first shaper 9 of a random pulse sequence, elements And 10 and 11, a reverse counter 12, an OR element 13, a second counter 14, a second random pulse shaper 15, a second register 16, a third random pulse shaper 17, a memory element 18, a second adder 19 modulo two.

The stochastic generator of Walsh functions works as follows. In the initial state, the counters 14, 12, register 16 and trigger 4 are reset. At the time of inclusion, the counter 1, the register 8 and the memory element 18 are set in a random position.

Clock pulses begin to arrive at the counting input of the counter 14, at the input of the shapers 9, 15 and 17, at the input of the closed element And 11 and at the counting input of the counter 1. Counter 1 generates Rademacher functions, which through a group of elements And 2 in accordance with the function number code Walsh, located in register 8, go to the inputs of the adder 3 modulo two. The Walsh functions generated by the adder 3 are fed to the second input of the second adder 19 modulo two. The signal from the output of the memory element 18 determines the polarity of the Walsh function, which will appear at the output of the generator. If at the moment the generator was turned on, the memory element 18 was set to the state “0”, then the Walsh function in the direct form is formed at the output of the adder 19 modulo two. If at the moment the generator was turned on, the memory element 18 was set to state “1”, then at the output of the adder 19 modulo two, the Walsh function is formed in inverted form. The states of the bits of counter 1 at each clock cycle of the generator represent the serial number of the element of the Walsh function in binary representation formed on this clock cycle.

For example, for option n = 3, the number of elements of the Walsh function N = 8 and the status of the bits of counter 1, corresponding to the serial numbers of the element of the Walsh function, are presented in Table 1.

Table 1 The status of the bits of the counter 1 (starting with the highest level) The serial number of the generated element of the Walsh function 000 0 001 one 010 2 011 3 one hundred four 101 5 110 6 111 7

But since at the moment the generator is turned on, counter 1 is set to a random position, the formation of the Walsh function begins not from the 0th element, but from any random one.

For example, if at the moment the generator was turned on, counter 1 was set to “101”, then the formation of the Walsh function starts from the 5th element, after which there is a formation of 6, 7, 0, 1, 2, 3, 4 elements, since the counter 1 counts clock pulses arriving at its counting input. Thus, the Walsh function with a random phase shift and random polarity, in direct or inverted form, is formed at the output of the generator.

Random pulses come from the shaper 9 to the closed element And 5 and through the open element And 10 to the summing input of the reverse counter 12.

After filling the counter 14, i.e. after all N elements of the Walsh function are generated, the signal from its output through the OR element 7 overturns the trigger 4, closing the generator output with the And 6 element and summing the input of the reverse counter 12 with the And 10 element and opens the And 5, And 11 elements.

Thus, by the time the trigger is switched to the generator output, a function is issued with the number specified by the code on register 8, with a random phase shift in accordance with the state of the bits of counter 1 at the moment the generator is turned on and with a random polarity determined by the state of memory element 18, and on the counter 12, a code is generated that determines the duration of the pause that follows the issued function.

After switching trigger 4, random pulses begin to arrive at the serial input of register 8 from the output of the shaper 9 through the open element And 5, to the serial input of the register 16 from the output of the shaper 15. Random pulses from the output of the shaper 17 are fed to the information input of the memory element 18. As a result, by the time of the next trigger 4 switchover, the random number of the next Walsh function will be recorded in binary representation in register 8, the random number of the element from which the formation of the Walsh function will start will be recorded in binary representation in register 16, and the memory element 18 will be written "1 "or" 0 ", determining the polarity of the generated Walsh function.

Clock pulses from the clock input of the generator through the open element And 11 begin to reduce the contents of the reverse counter 12 and at the time of resetting the counter 12 through the elements OR 13 and OR 7 to the control input of the parallel recording of the counter 1, the input of resetting the counter 14, the input enable recording element 18 and counting trigger input 4 receives a pulse. Moreover, in the bits of the counter 1 through its parallel input from the parallel output of the register 16 is written in binary representation the random number of the element from which the formation of the Walsh function begins, i.e. Walsh function having a random phase shift. At the same time, the counter 14 is zeroed, and also in the memory element 18, “0” or “1” is written from the output of the third shaper 17 of a random pulse sequence. At the same time, trigger 4 is overturned. At this, a pause of random duration ends and the next Walsh function starts to be issued with a number determined by register code 8, with a phase shift determined by the state of the bits of counter 1, and also with a polarity determined by the state of memory element 18.

Thus, the proposed stochastic generator of Walsh functions has wider functionality than the known generator, since it generates Walsh functions sequentially one after another with a random number, a random pause between functions, with a random phase shift of the generated Walsh functions and with random polarity Walsh functions, in direct or inverted form, which allows using the proposed stochastic generator of Walsh functions in stochastic inverters formations in devices of stochastic computing for the effective solution of probabilistic modeling and data processing problems, as well as in communication systems and networks, including those using LTE technology.

Claims (1)

A Walsh function stochastic generator containing a first counter, a first register, a group of AND elements, a first adder modulo two, a trigger, four AND elements, two OR elements, a first random pulse shaper, a reversible counter, a second counter, a second random pulse shaper and the second register, and the counting input of the first counter is connected to the clock input of the generator, the outputs of the same category of the first register are connected to the corresponding inputs of the corresponding element And the groups whose outputs are connected to the inputs of the first adder modulo two, the output of the first element OR is connected to the counting input of the trigger, the inverse output of which is connected to the first input of the first element And, the output of which is the output of the generator, the clock input of which is connected to the input of the first driver random pulse sequence, the output of the first driver of a random pulse sequence is connected to the first inputs of the second and third elements And, the second input of the second element And is connected to the first the fourth element And is connected to the direct output of the trigger, the second input of the third element And is connected to the inverse output of the trigger, the second input of the fourth element And is connected to the clock input of the generator, the output of the second element And is connected to the serial input of the first register, the outputs of the third and fourth elements And connected respectively to the summing and subtracting inputs of the reverse counter, the output of which is bitwise connected to the inputs of the second element OR, the output of which is connected to the first input of the first element nt OR, the counting input of the second counter is connected to the clock input of the generator, the zeroing input of the second counter is connected to the output of the second OR element, the overflow output of the second counter is connected to the second input of the first OR element, the input of the second shaper of the random pulse sequence is connected to the clock input of the generator, the output of the second a shaper of a random pulse sequence is connected to the serial input of the second register, the outputs of which are connected to the information inputs of the first counter, before recording permission of which is connected to the output of the second OR element, the outputs of the first counter are connected to the corresponding inputs of the elements of the And group, characterized in that a third driver of a random pulse sequence, a memory element and a second adder are modulo two, and the clock input of the generator is connected to the input of the third shaper of a random pulse sequence, the output of which is connected to the information input of the memory element, the recording permission input of which is connected to the output of the second electronic ment OR memory element output is connected to the first input of the second modulo two adder, a second input coupled to an output of the first adder modulo two adder output of the second modulo two is connected to the second input of the first element I.