SU407297A1 - DEVICE FOR MODELING THE CONTROL OF THE STATIONARYITY OF A RANDOM PROCESS - Google Patents

Description

one

The invention relates to the field of electrical modeling and is intended for modeling control equipment and for the study of the error stream when transmitting discrete information in KB radio channels.

Devices are known for determining the characteristics of non-stationary random processes, comprising parameters of a stationary random process, a scheme for introducing non-stationarity, the OR element and average and rms meters.

The operation of the proposed device is based on detecting a change in the time interval between emissions of a random process when measuring the average value of this process in the event of a violation of stationarity. Such a task occurs when discrete information is not distributed over a KB radio channel, where the mean value of errors in the transmitted information changes as the propagation conditions change. In the presence of a backup channel, the determination of the moment of change in the mean value of errors in the working channel allows timely switching of the stream of transmitted information to the backup channel, where at the moment of switching the distribution condition it is possible to transmit information with a smaller number of errors.

The proposed device is characterized in that in it the outputs of the average and

rms values are connected to the inputs of threshold sum selectors; we have a mean and rms value; and a mean and rms difference difference selector. The outputs of the selectors through the scheme "OR connected to the izmeretel time intervals ejection mn random process. The output of the meter is connected to the input of the integrator of time intervals and to one of the inputs of the subtraction circuit, the other input of the subtraction circuit is connected to the output of the integrator. The output of the subtraction circuit is connected to an increment integrator, which is connected to the input of the threshold circuit.

The drawing shows a block diagram. unbroken ycTpoiicTBa.

The source 1 of the stationary random process and the scheme of nonstandard 2 introduced through the element “OR 3 are connected to the meter 4 average and meter 5 root-mean-square values.

The outputs of the meters 4 and 5 are connected to the inputs of the threshold selectors 6 and 7, the sum of the average and rms and the difference of the mean and rms values. To the inputs of selectors 6 and 7, the output of the element “OR 3” is connected, and the outputs of the selectors are connected to the circuit of the element “OR 8. The output of the element“ OR 5 through a meter 9 time intervals is connected to the input of the integrator 10 time intervals. The integrator output is connected to one input of the subtractor 11, the other input of the subtractor is connected to the output of the meter 9 time slots.

The output of the subtraction unit P through the integrator 12 increments connected to the threshold circuit 13. Between the selectors 5 and 7 and the element "OR 8 installed keys 14 and 15.

The device works as follows.

Gauges 4 and 5 have a large integration constant and measure the parameters of a stationary random process coming from source 1. Selectors and 7 determine the random process intersection of the zone limited by the root-mean-square value. If key 14 is turned on, then all intersections are recorded in the upward direction; if key 15 is turned on, then all intersections are fixed in the downward direction of a random variable. The measured time intervals are averaged over integrator 10 and normalized by the number of current samples.

In subtraction unit 11, a comparison is made between the current time interval and the average of all previous time intervals.

The increment value obtained from the output of subtractor 11 is averaged at integrator 12 and compared with the threshold value in diagram 13.

When the introduction of non-stationarity 2 is turned on, the average value of the random process at the output of the element "OR 3" will start to change. Since the permanent integrations of the meters 4 and 5 are large, the thresholds of the selectors 6 and 7 do not change at the introduction of nonstationarity. In connection with this, the number of rms level rises increases, and

the measured time intervals at measurement output 9 is reduced.

On the integrator 10, the change in time intervals cannot immediately change the average value, therefore, at the output of the subtraction unit and the magnitude of the increment of the current value with respect to the average will increase, which after some integration of the increments will trigger the threshold

a scheme that indicates that the stationarity of the random process under investigation has been violated.

The verification of the proposed device was carried out by modeling on a NAIRI-2 computer.

Subject invention

Device for simulating control

the stationarity of the random process, which contains the source of the random process and the scheme for the introduction of non-stationarity, connected via the first element OR to the mean and mean square meter, and

keys, characterized in that, in order to expand the class of tasks, it contains threshold selectors, the inputs of which are connected to the output of the average meter, value, to the output of the average square meter, to the output of the first OR element, the second OR element, which keys are connected to the outputs of the threshold selectors, connected in series with the time interval meter,

an integrator of the time interval, a subtraction unit, an integrator for the increments of the time interval and a threshold circuit, the output of the second OR element is connected to a time interval meter connected to

subtraction unit.

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