SU474018A1 - Device for simulating the process of synchronizing the resonant phasing system - Google Patents

Description

The drawing shows a block diagram of the proposed device.

The device contains a generator of uniformly distributed random numbers 1 connected to the first input of the first key 2. The first key 2 is connected to the trigger 3. The output of the first key is connected to the inputs of the first n of the second selector 4 and 5 random numbers. The output of the selector 4 is connected to the first subtraction unit 6. The output of the generator 7 of a normally distributed random number is connected to another input of the first subtraction unit 6. The output of subtraction unit 6 is connected to the input of the first converter 8 of the uniform law of the distribution of random numbers into the normal law of the distribution of random numbers. The output of the selector 5 is connected to the input of the second converter 9 of the uniform law of the distribution of random numbers to the normal law of distribution. The output of the first converter 8 is connected to the first exponentially weighted integrator 10 and to one of the inputs of the second subtraction unit 11, to the other input of which the numbers from the output of the adder 12 are received. In turn, the output of the first ex-non-selective weighted integrator 10 is fed to one of the inputs of the third block subtract 13 and the input of the adder 12.

The output of the input unit of a constant number 14 is connected to the input of the adder 12. The output of the second converter 9 is connected to the input of the second exponentially-weighted integrator 15 and to the input of the fourth subtraction unit 16. The other input of the fourth subtraction unit 16 is connected to the output of the adder 12.

The outputs of the subtraction units 11 and 16 are connected to the OR 17 logic circuit, the output of which is connected to the input of the second key 18, the other input of which is connected to the trigger 3. The output of the second key 18 is connected to the input of the analyzer 19 of the rate of occurrence of numbers. The analyzer 19, in turn, is connected to trigger 3. The second output of this trigger is connected to the input of error counter 20.

Before starting, trigger 3 is reset. While the keys 2 and 18 are open, and the error counter 20 starts counting time. From the analyzer 19 tempo trigger 3 pulses are not received.

The generator of uniformly distributed random numbers 1 operates in the range of numbers O-1.0. The total number of numbers that the generator can produce is specified in advance by the discretization step of the numbers and their size. The numbers generated in the generator through the key 2 arrive at two selectors 4 and 5 random numbers. The selector 5 skips the numbers in the range O-0.5, and the selector 4 - in the range 0.5-1.0. From the output of the selector 4, random numbers are fed to one of the inputs of the first subtraction unit 6. The number 0.5 is continuously fed to its other input. It is generated in the generator 7. In the first subtraction block 6

the difference between random numbers in the range 0.5-1.0 and the number 0.5 is calculated, i.e., at the output of the first subtraction unit 6, random numbers appear in the range O-0.5. It should be emphasized that at the output of the second selector 5 random numbers, random numbers also appear in the range O-0.5. However, random numbers appearing at the output of subtraction unit 6 in the range O-0.5,

correspond to the original range of 0.5-1.0. Thus, the entire diaozone of random numbers O-1.0 overlaps.

The obtained random numbers from the selector 5 and the subtraction unit 6 are transmitted to converters 9 and 8 of the uniform law of the distribution of random numbers to the normal law of the distribution of random numbers. The 1 maximum of the normal distribution curve is set to the corresponding number equal to 0.25,

i.e., at the outputs of both converters 8 and 9, random numbers are distributed according to a normal law with respect to an average value of 0.25. From the output of each converter, random numbers are fed to the integrator and the subtractor. Accordingly, from converter 8 to the first integrator 10 and to the second subtraction unit 11, and from converter 9 to the second integrator 15 and the fourth subtraction unit 16. The integrators 10 and 15 are integrators with an exponential-averaged average and their outputs are connected to the third subtraction unit 13 and to the adder

12 (the output of the subtraction unit is also connected to the adder).

At the output of subtraction unit 13, numbers are formed in the D-azone O-0.25, and on the output of the adder 12 - in the range O-0.5. The purpose of subtraction unit 13 is to eliminate ambiguity while fixing the in-phase moment. At the moment of phase synchronization, the output of each of the integrators 10 and 15 is the number 0.25. In this case, the output of the subtraction unit

13 will be the number “Oh, and at the output of the adder 12 - the number-0.5.

The random numbers from the output of adder 12 are fed to subtraction blocks 11 and 16, and from them to the logical scheme "OR 17.

The input block of another number 14 is connected to the adder 12 and serves to simulate a phase shift.

From the scheme "OR random numbers through the second key 18 are fed to the analyzer 19

the darkness of the numbers 9, greater than the numbers taken from the adder 12. Since the output of the adder is 12, the numbers constantly increase from 0 to 0.5, until the moment of synphase all the numbers coming to the OR or less than 0.5, are errors. These errors are accumulated in the rate analyzer 19, where the law of variation in the number of errors is calculated over the time interval from the moment of switching on until the moment of phase synchronization. The limits of the analyzer can be preset