SU828103A1 - Device for measuring amplitude-modulated signal non-linear distortion - Google Patents

Description

The invention relates to electrical engineering and can be used to create devices for monitoring the transmission paths of amplitude-modulated (AM) signals. 5

A device for measuring the nonlinear distortion of AM signals, comprising two sound generators, an AM receiver. signals, AM detector and selective amplifier [1]. The disadvantage of this device is the impossibility of measuring the nonlinear distortions introduced by the path itself.

Closest to the invention in technical essence is a device 15 containing two modulating sound generators, the first output of the first of which is connected to one of the inputs of the amplitude modulator, the other input of which is connected to the first output of the high-frequency _20th oscillator, and sequentially connected receiver of AM signals and selective indicator [2].

The aim of the invention is to increase the resolution. ₂₅

This is achieved by the fact that the known device for measuring nonlinear distortion of amplitude-modulated signals in their transmission paths, containing two modulating sound generators, the first output of the first of which is connected to one of the input of the amplitude modulator, the other input of which is connected to the first output of the high-frequency a master oscillator, and a series-connected receiver of amplitude-modulated signals and a selective indicator, is equipped with two low-frequency attenuators, two low-frequency phase shifters switches, three high-frequency phase shifters, a high-frequency phase meter, a switch, two adders and three additional amplitude modulators, the first input of the first of which is connected to the first output of the master high-frequency generator, the second input - with one of the outputs of the second modulating sound generator, and the output through the first high-frequency phase shifter connected respectively to one of the inputs of the first adder and through the switch to the first input of the high-frequency phase meter, the output of the main amp the bulk modulator is connected respectively to the other input of the first adder and, through the switch, to the second input of the auxiliary phase meter, the second output of the first modulating Sound generator through the first low-frequency phase 3 connected in series

The caller and the first low-frequency attenuator are connected to one of the inputs of the second additional amplitude modulator, the other input of which is connected to the second output of the master high-frequency generator, and the output through the second high-frequency phase shifter is connected respectively to the first input of the second adder and through the switch to the first input of the high-frequency phase meter, the other the output of the second modulating sound generator through a series-connected second low-frequency phase shifter and a second low-frequency This attenuator is connected to one of the inputs of the third additional amplitude modulator, the other input of which is connected to the second output of the master high-frequency generator, and the output through the third high-frequency phase shifter is connected respectively to the second input of the second adder and through the switch to the second input of the high-frequency phase meter, the output of the first adder is connected with the input of the test path, and its output is connected respectively to the third input of the second adder and through a switch with inputs high-frequency a phase meter, the output of the second adder is connected to the input of the receiver of the amplitude-modulated signals.

The drawing shows a structural electrical diagram of the device.

It contains modulating sound generators 1 and 2, the master high-frequency generator 3, the main amplitude modulator 4, the test path 5, the receiver 6 AM signals, a selective indicator 7, additional amplitude modulators 8, 9 and 10, high-frequency phase shifters 11, 12 and 13, low-frequency phase shifters 14 and 15, low-frequency attenuators 16 and 17, adders 18 and 19, high-frequency phase meter 20 and switch 21.

The device operates as follows.

The voltages from the outputs of modulating sound generators 1 and 2 are supplied to the inputs of the amplitude modulators 4 and 8, which also receive voltage from the master high-frequency generator 3. At the outputs of these amplitude modulators, voltages are formed that contain components due to the nonlinearity of the modulators. The high-frequency phase shifter 11 provides phase-carrier oscillations at the inputs of the adder 18, which is controlled by a high-frequency phase meter 20. The voltage from the output of the adder 18, containing only spectral components with frequencies of modulating sound generators, is fed to the input of the test path 5. Due to distortions in the test path in the output voltage additional harmonics of the modulating frequencies and their combinations appear.

Using a master high-frequency generator 3, a modulating sound generator 1, a low-frequency phase shifter 14 and a low-frequency attenuator 16, another modulated voltage is generated at the output of the amplitude modulator 9. High-frequency phase shifter 12 compensates for the non-phase state of this voltage with the voltage at the output of the test path 5.

Similarly, using a master high-frequency generator 3, a modulating sound generator 2, a low-frequency phase shifter 15, and a low-frequency attenuator 17, another modulated voltage is generated at the output of the amplitude modulator 10, the non-phase of which with the voltage at the output of the amplitude modulator 9 is compensated by the high-frequency phase shifter 13.

The voltages from the outputs of the amplitude modulators 9 and 10 are fed to the inputs of the adder 19, the output voltage of which takes into account the changed resulting amplitudes and the phase of the harmonics. As a result of adjustments using low-frequency phase shifters 14 and 15 of the low-frequency attenuators 16 and 17, harmonics are eliminated with the frequencies of the modulating voltages in the output voltage of the adder 19. This voltage is detected in the receiver 6 AM signals, and the amplitudes of the components of the combined total frequencies at the output of the receiver 6 AM signals measured by selective indicator 7.

They determine the nonlinear distortions of the law of amplitude change, introduced by the studied path 5. According to the results of measuring the amplitudes of the total combination components, the harmonic coefficient is calculated. Since the components of the Raman frequencies do not occur in amplitude modulators, adders, and the receiver, the intrinsic nonlinear distortions of the amplitude modulators and the receiver do not affect the measurement result of the distortions introduced by the studied path. This allows you to get in the device a high resolution measurement when using modulators and receivers (detectors), the linearity of which is not high.

Claims (2)

1.Mishchenko A.G. On the issue of measuring nonlinear distortion AM. transmitters. Questions radio electronics, ser. Radio measuring technique, 1972., vol. 3, s. 95 2. Bank M. U. Electrical and Acoustic Parameters of Radio Receivers .- M., “Connection 1974., p. 158-162 (prototype).