SU365658A1 - ANALYZER OF THE AMPLITUDE AND PHASE OF HARMONIC NONRAYODIC STRESSES - Google Patents

Description

one

The invention relates to the field of radio metering technology and can be used as an independent device for measuring the amplitude and phase of periodic voltage harmonics in the study of nonlinear elements and devices.

Amplitude and phase harmonic analyzers are known, which contain a channel of change and a channel for the formation of a switching voltage, built on the principle of simultaneously analyzing the input voltage. The disadvantage of such analyzers is a significant measurement error of both amplitude and phase.

The aim of the invention is to reduce the amplitude and phase measurement errors and to eliminate the switching of the frequency-supply circuit of an adjustable oscillator.

In the proposed analyzer, this goal is achieved by applying an additional frequency divider (the total division ratio of the main and additional dividers is equal to the smallest common multiple of the numbers of measured harmonics) and the synchronization circuit. This makes it possible to eliminate switching of the frequency-setting circuit and reduce the measurement error of the amplitude and phase of the harmonics.

The functional diagram of the analyzer is shown in the drawing.

The measurement channel has an input device /, an active notch filter 2 for suppressing the main harmonic, an attenuator 3, an amplifier 4, synchronous detectors 5 and 6, indicators 7 and 8, connected in series. The switch voltage shaping channel consists of a phase detector 9, a fundamental frequency divider 10, a low-pass filter 11, an error amplifier 12,

adjustable generator / 5, quadrature voltage shaping circuit 14, additional frequency divider 15 forming device 16 (synchronization circuit). The analyzer works as follows:

the input signal under study through the input device 1, the active notch filter 2, the attenuator 3 and the amplifier 4 are fed to two synchronous detectors 5 and 6. The reference voltage from the frequency first harmonic is fed to the phase detector 9, to the second input of which comes the voltage from the main frequency divider, the signal to which the adjustable oscillator 13 is supplied through an additional frequency divider 15 and the circuit

forming quadrature voltages 14. The error signal, proportional to the phase difference, in the form of a constant voltage is fed through a low-pass filter 11 and the error amplifier 12 to a tunable generator 13 and changes its frequency and

phase in the direction of decreasing the phase mismatch. At the same time, the pulses formed in the shaping device 16, when the reference voltage passes through zero, arrive at the synchronization input of the adjustable oscillator 13 n and reduce the phase mismatch to a minimum.

Since the product of the division coefficients of the main and additional frequency dividers is equal to the smallest total of the numbers of measured harmonics, when both dividers are switched simultaneously (the division ratio of the main is equal to the number of the measured harmonic, and the additional one is the lowest total divided by the harmonic) the division ratio remains constant. Due to this, the frequency-dependent circuit of the adjustable oscillator is not switched and the measurement error is reduced.

Subject invention

The amplitude and phase analyzer of periodic voltage harmonics, containing a measurement channel and a switching voltage shaping channel, including an automatic phase adjustment circuit with a frequency divider in the adjustable oscillator circuit and a quadrature voltage shaping circuit, in order to reduce the amplitude measurement error and phases of harmonics and switching exclusion of the adjustable oscillator, the analyzer is equipped with an additional frequency divider, the input

which is connected via a tunable generator to the output of the synchronization circuit, and the output through a quadrature voltage shaping circuit, the main divider and the phase detector with the reference voltage source and to the input of the synchronization circuit.

Jon (t)