SU1396081A1 - Amplitude-phase analyzer of harmonics of periodic voltages - Google Patents

Abstract

The invention relates to the field of creating analyzers of a complex spectrum of periodic signals and can be used in the study of signal-responses, for example, in vibrometry. The amplitude-phase analyzer contains an input block 1, a notch filter 2, an attenuator 3, an amplifier 4, synchronous detectors 5 and 6, indicators 7 and 8, a quadrature reference voltage shaping unit 9, comparators 10 and 11 voltages, and random generators 19 and 20 stress By introducing two functional conversion units 12, it is possible to reduce the dispersion of the harmonic components of the rectangular weight function that is used in the device, which improves the measurement performance. Reducing the measurement error makes it possible to reduce the measurement time interval or increase the speed of the device. The description provides an example of implementation of the functional conversion block 12. 1 z.p, 4g - ly, 2 ill. c (o

Description

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The invention relates to measuring techniques, in particular, to the creation of analyzers of the complex spectrum of periodic signals, selective microvoltmeters and nonlinear distortion meters, and can be used in the study of signal responses in vibrometry, acoustics, geological prospecting, and solid state physics. ,, biology and t „d. The purpose of the invention is to increase the speed; measurements by introducing into the Channelizer two functional transformation units, with the help of which it is possible to reduce the dispersion of the harmonic components of the square weight function that is used in the device with the Unloading Error: the measurements can reduce the time interval of the measurements or increase the speed of the device with the same prototype measurement errors.

FIG. 1 shows a structural analyzer circuit; in fig. 2 is a diagram of its functional transformation block.

The amplitude-phase analyzer of periodic voltage harmonics contains a series-connected input unit 1, a notch filter 2, an attenuator 3, an amplifier 4, the first 5 n and the second 6 synchronous detectors, the outputs of which are connected respectively to the inputs of the first 7 and second 8 indicators, quadrature reference voltage generating unit 9, quad1) whose outputs through the first 10 and second 11 voltage comparators are connected to the reference inputs of the first 5 and second 6 synchronous detectors, respectively, as well as two function blocks 12 conversion (Fig. 2), each of which contains m modulators 13, ha of voltage comparators 14, ha of summing amplifiers 15, and also one adder 16, a module former 17 and a reference voltage source 18, with the first input of m comparators 14 are combined and, through the shapers, 17 modules are connected to the corresponding stages of the quadrature reference voltage generation unit 9, the first inputs are

the summing amplifiers 15 are combined and connected to the outputs of the respective sources 18 of the reference voltage, the outputs of the first 19 and second 20 random voltage generator su; 0 5 0

5 0 5 0 d

five

connected to the second inputs of the summing amplifiers 15 blocks 12, respectively, the outputs of which are connected to the corresponding second inputs m of the comparators 14, the outputs of the latter are connected to the controlled inputs of the corresponding modulators 13, the signal inputs of which are combined and connected to the output of the amplifier 4, and the outputs through the mators 16 - to the signal inputs of the first 5 and second 6 synchronous detectors, respectively.

Modulators can be made on identical keys, and a module driver can be made on two operational amplifiers and four diodes.

The analyzer works as follows.

The input variable voltage under study is through the input unit 1, notch filter 2, attenuator 3 and amplifier 4 is fed to the inputs of the modulators 13 of two blocks 12. To simplify the presentation, we will consider the analyzer's work in the future to measure only one quadrature component of the harmonic under study, for example, the channel of blocks 12, 5 and 7, since the operation of the device when measuring the second quadrature component (through the channel of blocks 12, b and C) is similar. After modz. l 1 in blocks 13 and summation with certain weights in the adder 16 input: the signal is fed to the input of the synchronous detector 5 "The input reference voltage with the frequency of the first harmonic of the input signal under study is fed to the input of the quadrature reference voltage shaping unit 9, representing a frequency multiplier which forms two quadrature reference voltage variables with exactly the frequency of the input reference signal multiplied exactly n times synchronized with the latter, in the particular and most important practice case when harmonic orthogonal weighting functions are required, the output voltages of the formative 9 must be sine, of a distal form. The random voltage generator 19 (20) forms a random voltage with a uniform distribution law. Then, when specifying certain summation and gain factors of summing amplifiers 15 and adder 16, an average weighting function will be obtained

sinusoidal transformations, the dispersion of the harmonic coefficients of which is significantly reduced compared with the weight function of the prototype analyzer.

It is a known fact that the longer the measurement time, the smaller the measurement error, and vice versa.

To obtain the permissible value of the error can be different. In the prototype analyzer, for example, to obtain an error of + 3%, a measurement time interval of at least 100 Tf is required, where T is the period of the measured harmonic, and in the proposed analyzer already at m 2 this error is reached in a time interval of duration, because The introduction of additional units in the proposed device reduces the measurement time.

Claims (2)

1. Amplitude-phase analyzer of periodic voltage harmonics, containing serially connected input unit, notch filter, attenuator, amplifier, as well as first and second synchronous detectors, whose outputs are connected to the inputs of the first and second indicators, respectively, quadrature reference voltage generation unit The quadrature outputs of which are connected via the first and second voltage comparators to the reference inputs of the first and second synchronous detectors, respectively, and two random generators eny, characterized in that, in order povsch1eni speed, two pre functional unit introduced therein ten 15 20 25  , thirty 35 40 formation, the inputs of which are combined and connected to the output of the amplifier, and the outputs are connected respectively to the signal inputs of the first and second synchronous detectors, while the second and third inputs of the first functional conversion unit are connected respectively to the output of the first random voltage generator and the first output of the quadrature reference generator voltages, and the second and third inputs of the second functional conversion unit are connected respectively to the output of the second random voltage generator and orym quadrature output of the reference voltage. 2. The analyzer according to claim 1, characterized in that the functional conversion unit comprises a module driver, whose input is the third input of the module, a reference voltage source, an adder, m modulators, m comparators and m summing amplifiers, the first inputs of which are combined and connected to the output of the reference voltage source, and the combined second inputs are connected to the second input of the functional conversion unit, while the first inputs of the modulators are combined and connected to the first input of the functional conversion unit and their second inputs connected to the outputs of respective comparators ,, and outputs - to the inputs of an adder whose output is an output of the conversion function, the first inputs of the comparators are combined and connected to the output of the modulator, and their second inputs connected to the outputs of the respective amplifiers. Fie.2