CS240660B1 - Transfer function determination connection with possibility of noise suppression - Google Patents

Abstract

The engagement can be a modulation process to carry out the transformation of the monitored signal both the constant frequency and the the frequency approaching zero and so much narrow the bandwidth. The wiring can be used for diagnostic purposes measurements in engineering, especially vibration evaluation.

Description

(54)

Connection for determining the transmission function with the possibility of noise suppression

By connection, the modulation process can be used to transform the monitored signal to a constant frequency and to a frequency approaching zero, thus substantially narrowing the bandwidth. The connection can be used for diagnostic measurements in mechanical engineering, especially for evaluation of vibrations.

240 BGO

240 660

240 660

The invention relates to a circuit for determining a noise-canceling transmission function which solves the problem of finding the transmission function of an electrical or electromechanical circuit in automatic measurement.

For various technical tasks, it is necessary to determine the response of a periodic signal that passes through the measured electrical or electromechanical circuit. Due to internal nonlinearities or the formation of an additional disturbing signal, a periodic non-harmonic signal appears at the output of the measured circuit, containing in addition to the basic periodic harmonic component various

- 2 240 660 amount of other harmonic components. Finding the ratio of the amplitude dependence of the first harmonic component of the output signal relative to the artplitude of the first harmonic component of the input signal at a variable frequency is a task to determine the transmission * A similar illness is solved for phase ratios between the input signal and the output component of the first harmonic. This problem is usually solved by analyzers working on various principles, such as selective filtration, multiplier, realization of Fourier coefficient, etc. Implementation of continuous operation in a wider frequency range is difficult to implement especially because selective filters cannot be translated over a wide range frequency band - e.g. 5 to 5000 Hz. Performing analysis using a multiplier encounters difficulties in frequency and voltage range and needs special components. A solution using a mixing system is also known, but a complex modulation and demodulation process is required to obtain the transfer function. The input signal from the sensor must be modulated to the carrier frequency, the modulators used must be linear in the range of several orders and it is necessary to create phase shifted components.

The above drawbacks are overcome by the noise suppression circuitry of the present invention, wherein the first oscillator is coupled by its output to the first input of the first modulator, the second input of which is the output of the second oscillator, which is also coupled to the first the input of the second modulator and the first input of the third modulator, the output of the first modulator being coupled to the input of the first low-pass filter, the output of which is connected to the first input of the first switch; measured object to which

At the same time, a second sensor is connected to the second input of the third modulator, the second output of the first sensor being connected to the second input of the second modulator whose output is connected to the input of the first bandpass filter and the output of the third modulator is connected to the input of the third modulator.

the second bandpass filter and the output of the first bandpass filter are connected both to the first input of the phase meter and to the input of the fourth modulator and the output of the second bandpass filter is connected both to the second input of the phase meter and to the first input of the fifth modulator and the fifth modulator is connected to the output of the first oscillator and at the same time the first output of the fourth modulator is connected to the low-pass filter input and the first output of the fifth modulator is connected to the input of the third low-pass filter. the third low-pass filter is connected to the input of the second voltmeter, the output of the first voltmeter being connected to the first input of the ratio circuit to whose second input the output is connected to the second voltmeter.

The output of the phase meter is connected to the first input of the second switch, the second input of which is the output of the ratio circuit, the output of the second switch is connected to the first input of the recorder, to the second input of the controller. The second input of the first switch is connected to another generator.

240 060

The circuitry of the present invention eliminates the problems of converting the signal to the carrier frequency, the difficulties arising from complex modulation and demodulation processes, the complications of generating phase-shifted signals throughout the measurement band. The advantages of the circuitry are that it is possible, by means of the modulation process, to transform the monitored signal to a constant frequency corresponding to a fixed frequency oscillator and to a frequency approaching zero, thereby substantially narrowing the bandwidth. The modulators used can be of low switching type.

The accompanying drawing shows an exemplary circuit according to the invention.

The first oscillator 1 is connected to the first input of the first modulator 3, the second input of which is connected to the output of the second oscillator 2, which is also connected to the first input of the second modulator 10 and the first input of the third modulator 11. a first low-pass filter 4, the output of which is connected to the first input of the first switch 5 ,. The output of the first switch 5 is connected to the input of the actuator 6, which is connected via the first sensor 7 to the measured object 8, to which the second sensor 9 is connected, the output of which is connected to the second input of the third modulator 11. 7 is connected to the second input of the second modulator 10, the output of which is connected to the input of the first bandpass filter 12 and the output of the third modulator 11 is connected

5,240,660 to the input of the second bandpass filter 13 and at the same time the output of the first bandpass filter 12 is connected to the first input of the phase meter 14 and to the first input of the fourth modulator 15 and the first input of the fifth modulator 16 is connected to the output of the first oscillator 1. The first output of the fourth modulator 15 is connected to the input of the second low-pass filter 17 and the first output of the fifth modulator 16 is connected to the input of the third low-pass filter 18. the output 17 of the second low pass filter is connected to the first input of the voltmeter 19 while the output of the third low-pass filter 18 is connected to the input of the voltmeter ^20. ýstup first voltmeter 19 is connected to the first input of the ratio circuit 21 to the second the input is connected to the second output voltmeter 20.

The output of the phase meter 14 is connected to the first input of the second switch 22 _t , the second input of which is connected to the input of the ratio circuit 21. The output of the second switch 22 is connected to the first input of the recorder 23 and second oscillator input 2. The second input of first switch 5 is coupled to another generator 25.

By means of the first fixed frequency oscillator 1, the second variable frequency oscillator 2, the first modulator 3 and the first low-pass filter 4, a mixing generator system is created, the control signal of which is

6 240 660 of the first switch 5, which makes it possible to connect this signal or a signal from another generator 25 to the input of the actuator 6, or both in a certain ratio. It is also possible to carry out measurements in the self-excitation of the measured object (8) by external influences. Information on the input and output measured value on the measured object 8 is obtained in the first sensor 7 and second sensor 9, where it is fed to the second input of the second modulator 10 and the third modulator 11. The first inputs of the second and third modulators 10, 11 are supplied with a periodic signal from the second variable frequency oscillator 2. The resulting modulation product, comprising the summation component of the signal, passes through the first band-pass filter 12 and the second band-pass filter 13, the output of which is supplied both to the inputs of the phase meter 14 and to the first inputs of the fourth modulator 15 and the fifth modulator 16. periodic signal of the first oscillator 1 with fixed frequency. The resulting products containing the differential frequencies pass through the second low-pass filter 17, the third low-pass filter 18 and arrive at the inputs of the first voltmeter 19 and the second voltmeter 20 from which the signal is fed to the ratio circuit 21. This circuit produces an output signal proportional to the ratio logarithms. By means of the second switch 22 it is possible to automatically record the transmission or phase characteristics on the recorder 23, where the first input receives information for the second switch 22 from the phase meter 14 or the ratio circuit 21 and the second input the control voltage from the controller 24 of the second oscillator 2 and thus proportional to the frequency change of the entire mixing generator.

Claims (3)

Object of the invention 240 660 A circuit for determining a noise-canceling transmission function, characterized in that the first oscillator (1) is connected to the first input of the first modulator (3), the second input of which is connected to the output of the second oscillator (2), with a first input of the second modulator (10) and a first input of the third modulator (11), the output of the first modulator (3) being connected to the input of the first low-pass filter (4), the output of which is connected to the first input of the first switch; is connected to the input of the actuator (6), which is connected via the output through the first sensor (7) to the measured object (8), to which is connected the second sensor (9), whose output is connected to the second input of the third modulator (11) wherein the second output of the first sensor (7) is coupled to the second input of the second modulator (10), the output of which is connected to the input of the first band-pass filter (12) and the output the third modulator (11) is connected to the input of the second band-pass filter (13) and the output of the first band-pass filter (112) is connected both to the first input of the ferrometer (14) and to the input of the fourth modulator (15) (13) is connected to the second input of the phase meter (14) and to the first input of the fifth modulator (16), the second input of the fourth modulator (15) and the fifth modulator (16) being connected to the output of the first oscillator (1) 8 ' 240 660 degrees of the fourth modulator (15) is connected to the input of the second low-pass filter (17) and the first output of the fifth modulator (16) is connected to the input of the third low-pass filter (18), the input of the first voltmeter (19) and the output of the third low-pass filter (18) is connected to the input of the second voltmeter (20), the output of the first voltmeter (19) is connected to the first input of the ratio circuit (21) a second voltmeter (20). Wiring according to claim 1, characterized in that the output of the phase meter (14) is connected to the first input of the second switch (22), to the second input of which the output of the ratio circuit (21) is connected. the input of the recorder (23) to which the second input is connected to the output of the controller (24) which is also connected to the input of the second oscillator (2). Connection according to Claims 1 and 2, characterized in that the second input of the first switch (5) is connected to another generator (25).