CS251885B1 - Wiring to measure the relative frequency of pulses favorable to the realization of a pulse random process - Google Patents

Abstract

The connection concerns the measurement of the relative frequency of pulses favorable to the implementation of the pulse process, which allows the detection of static regularities, in particular the probability of the occurrence of the expected phenomenon of the pulse random process. The essence of the connection lies in the fact that the first output of the pulse random process source is connected to the input of a frequency meter, the output of which is connected to the first input of a frequency divider with a variable division ratio, the second input of which is connected to the second output of the pulse random process source and the output of which is connected to the mean frequency meter. The connection can be used in the measurement of randomly occurring physical quantities that are marked by electrical pulses, in particular in the measurement of the velocity fields of aircraft engine compressors.

Description

BACKGROUND OF THE INVENTION The invention relates to a circuit for measuring the relative frequency of pulses favorable to the pulse process, which has enabled them to ascertain statistical regularities, in particular the probability of occurrence of a presumed pulse random process effect.

When measuring physical quantities that are the realization of a pulse random process, there are usually electrical pulses indicating each measurement realization and electrical pulses indicating the realization of the measurement with a favorable result. The ratio of the number of pulses with a favorable result to the total number of realizations of the pulse random process is a quantity relative to the optimization of measurements to the maximum number of favorable realizations. The prior art connections for pulse rate measurements are either analog or digital, and the analog pulse rate measurement consists of measuring the mean value of the pulse train over time. Short pulses of one polarity and of the same shape and size are fed to an integrator, n, and whose output is usually a voltage proportional to the frequency of the input pulses over time. The digital connections for the pulse rate measurement consist of measuring the number of pulses that occurred in the indicated time interval by means of a pulse counter. In both cases, the relative pulse rate of the pulse random process is calculated by dividing the pulse rate of the favorable realizations by the pulse rate of the total number of pulse random process implementations.

The disadvantage of these wiring is that the relative pulse rate of the favorable pulse randomization process is calculated by dividing the results of two parallel pulse rate meters, assuming the same characteristics of the measuring instruments used, thereby increasing the demands on the measuring instruments used in the current connection. reducing the reliability of measurements of the relative frequency of the pulse, random process.

These disadvantages are eliminated by the circuitry for measuring the relative pulse rate of the favorable pulse randomization process of the present invention, wherein the first pulse randomization source output is connected to a frequency meter whose output is connected to a first frequency divider input with a variable split ratio. the second input of which is connected to the second output of the pseudo-pulsating non-pulsating source, and whose output is when the amplitude of the forward frequency rhythm is calculated.

The yield of the stacked circuit is that the average frequency meter is a measured number of pulses without the need for further mathematical operations, thereby increasing the measurement speed.

A further advantage is that it is not necessary to use two identical sets of measuring instruments in the measurement, thereby increasing the reliability of the measurement of the relative frequency of the pulse random process.

An example of a circuit for measuring the relative pulse rate of a favorable pulse randomization process is shown schematically in the attached drawing.

The first output of the pulse random process source 4 is connected to the input of the frequency meter 1. The data output of the frequency meter 1 is connected to the first input of the frequency divider 2 with a variable split ratio, to the second pulse input of which the second output of the pulse random process source 4 is connected. The output of the frequency divider 2 is connected to the average frequency meter 3.

The numeric code value at the output of the frequency meter 1 expresses the frequency of pulses that have passed from the output of the total number of pulse random process implementations of the pulse random process source 4 to the input of the frequency meter 1 per unit of time.

The average number of pulses per output of the frequency divider 2 is determined by the ratio of the pulse rate favorable to the pulse random process realization that passed from the pulse output positive realization of the pulse random process source 4 to the pulse input of the frequency divider 2 the numerical value of the code that is fed to the split ratio determining the input of the frequency divider 2 with the variable split ratio from the data output of the frequency meter 1. By means of the Mean Frequency Value Meter 3, the measured variable number of pulses applied to its input from the output of the frequency divider 2 with a variable dividing ratio is an expression of the relative frequency of pulses favorable to the implementation of the Pulse random process.

The present invention can be used in the measurement of randomly occurring physical quantities, which are indicated by electrical impulses, in particular in measuring the velocity fields of aircraft engine compressors.

Claims (1)

A wiring for measuring the relative pulse rate of a favorable pulse: random process implementation characterized in that the first output of the pulse random process source (4) is connected to an input of a frequency meter (1) whose output is connected to a first INVALID input of a frequency divider (2) with a variable split ratio, the second input of which is connected to the second output of the pulse: random process source (4) and whose output is connected to the average frequency meter (3).