SU866493A1 - Device for measuring coefficient of harmonics - Google Patents

Description

(54) DEVICE FOR MEASURING THE HARMONIC RATIO

Claims (2)

This invention relates to a radio metering technique and is intended to measure the harmonic components of generators and amplitude-modulated signal receivers. The closest in technical terms to the present invention is a device containing a source of modulating voltage, an amplitude modulator, an admitted generator, a receiver and a spectrum analyzer til. However, the resolution of the known device is insufficient. The purpose of the invention is to increase the permissibility of measurement capabilities. The delivered sensor is achieved by the fact that a harmonic coefficient measuring device containing a voltage source modulated to the input of the amplitude modulator, the second input of which is connected to the output of the master oscillator, as well as the receiver and spectrum analyzer, is added to a device for measuring the coefficient of harmonics, high-frequency phase rotator, frequency multiplier, low-frequency phase-effect detector and attenuator, P The first adder is connected between the output of the amplitude modulator on the input of the amplifier, the high-frequency phase-shifter The first adder is connected between the master clock oscillator and the BTOfOiiM input, the second adder is connected between the output of the receiver and the analyzer's input, a frequency multiplier connected in series, a low-frequency phase rotator and an attenuator are connected between the second and modulated source and the second the entrance of the second summatf. The drawing shows a block diagram of the proposed X1 device. The device contains a source of 1 modulated voltage, an amplitude motor: a blower 2, an adder 3, a receiver 4, a second adder 5, a spectrum analyzer 6, reduce the 7 frequencies that drive the generator B, the high frequency phase shifter 9, the low frequency phase shifter 10 and the attenuator 11. The device works as follows. In the first measurement, the signal from the output of the amplitude modulator is passed through the adder 3 to the input of the receiver 4 without compensation with the voltage at the second input of the adder 3. From the output of the receiver 4, the envelope enters the adder 5, here it is added to the harmonic voltage received during the attenuator 11. The low-frequency phase shifter 10 and the attenuator 11 achieve compensation of the measured harmonic in the adder 5, which is indicated by the spectrum analyzer 6. Using the spectrum analyzer 6, the amplitude of the uncompensated harmonics is determined, and the position of the low-pass phase shifter switch indicates the phase at the moment of harmonic compensation. In the second measurement, 3 oscillations are generated from the output of modulator 2, oscillations from the output of the high-frequency phase shifter 9. Then, using a low-frequency phase shifter 10 and an attenuator 11, compensate for the measured even harmonics in the adder 5. When the amplitude modulated signal passes through the receiver 4, additional components appear in its envelope due to non-linear distortions of the receiver 4. In the second dimension, all the signal components are shifted by 180 with respect to the signal components at the first measurement. At the same time, the components of even harmonics arising in receiver 4 are shifted by an angle,; a multiple of 36 °, so that the resulting even harmonics at the output of the receiver differ in the first and second measurements. The components of the odd harmonics appearing in the receiver 4 are rotated through an angle of 180 + + p360 °, where 1, 2, 3 ..., therefore, the resulting odd harmonics at the receiver output in the first and second measurements have the same magnitude. Next, the amplitude and phase of the harmonic arising in the receiver 4 and at the output of the amplitude modulator are determined from the vector diagram. 2. The harmonic coefficient is determined by measuring the magnitude of the ne harmonic of the modulating oscillations with the analyzer 6 Uo where and, 2 is the amplitude of the second harmonic; and - the amplitude of the first harmonic. The K determined in this way will differ from the total coefficient determined for all harmonics, no more than 12%. Thus, the increase in measurement resolution is achieved by measuring the amplitude and phase of the four harmonic voltage at the output of receiver 4 twice, and in the second measurement the envelope of the amplitude-modulated oscillation at the input of receiver 4 is rotated 180 by adding it to the sinusoidal oscillation carrier frequency, having an amplitude twice as large as the amplitude of the amplitude amplitude-modulated oscillation, and shifted relative to it by l8O °. At the same time, the even harmonics of the amplitude-modulated oscillations arising in the generator 8 are rotated 180 °, and the even harmonics arising in the receiver 4 are rotated by an angle of 36 °. An apparatus for measuring a harmonic coefficient, containing a source of modulating voltage, connected to an input of an amplitude modulator, the second input of which is connected to the output of a master oscillator, as well as a receiver and spectrum analyzer, in order to increase the resolution to it additionally introduced two adders, a high-frequency phase shifter, a frequency multiplier, a low-frequency phase shifter and an attenuator, the first adder being connected between the output of the amplitude modulus ora and receiver input, a high frequency phase shifter is connected between the output of the master oscillator and the second input of the first adder, a second adder is connected between the output of the receiver and the input of the spectrum analyzer, serially connected frequency multiplier, low frequency phase shifter and attenuator are connected between the second output of the modulated source and the second input of the second adder. Sources of information taken into account in the examination 1. Bank M. U. Electrical and acoustic parameters of radio receivers. M .. Holy Hour, 1974, p. 159. Yu esl "Ъ