RU2565424C1 - Harmonic signal shaper - Google Patents

Abstract

FIELD: instrumentation.

SUBSTANCE: invention relates to electronics and can be used in instrumentation and ACS. Claimed shaper comprises two input buses, two-channel amplitude stabilizer, multiplier, scaling amplifier and correction unit. The latter is composed by second and third multipliers and adder.

EFFECT: shaped signal with minimum nonlinear distortions at feed of triangular shaped signals to device input, their amplitude and frequency varying in the wide range and at notable asymmetry of signals amplitude.

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Description

The invention relates to the field of electronics and can be used in measuring equipment and automation.

A device is known (sine converter) [Titz U., Schenk K. Semiconductor circuitry: Reference manual. Per. with him. M .: Mir, 1982, Fig. 11.26], working on the principle of piecewise approximation and allowing to obtain a quasi-sinusoidal voltage from a triangular signal.

The disadvantages of the device include: a high distortion coefficient (0.42% at six break points of the approximating curve with a piecewise constant slope); significant error with a large input signal and a significant temperature error of the generated signal. With an increase in the number of breakpoints, such converters become more accurate, but also more complex [Dvornikov O. Sinusoidal voltage shaper. Modern Electronics, 2008, No. 6, p. 42-45].

A device is known [Dubrovin B.C., Zyuzin A.M. Harmonic signal generator. Pat. Russian Federation №108248, Н03В 28/00. Application: 2011119055/08, 05/12/2011. Published: September 10, 2011, Bull. No. 25], containing a controllable filter, a two-way limiter, an amplifier and a frequency-voltage converter, the output of a controllable filter connected to an amplifier input, the output of which is connected to an output of a harmonic signal former, the input of a harmonic signal former is connected to a two-way limiter input and input the frequency-voltage converter, to the output of which a control bus of the controlled filter is connected, and the output of the two-way limiter is connected to the input of the controlled filter.

The controllable filter is made of four of the same series-connected low-pass filters, the control inputs of which are connected to the control bus of the controllable filter, the input and output of which are connected, respectively, with the input of the first low-pass filter and with the output of the fourth low-pass filter.

The low-pass filter is made of an operational amplifier, a multiplier, a capacitor and two resistors, the capacitor being connected between the inverting input and the output of the operational amplifier, the non-inverting input of which is connected to the common bus, and the output is connected to the output of the multiplier, the second resistor is connected between the inverting input of the operational amplifier and the output of the multiplier, the control input of which is connected to the control input of the low-pass filter, while the first resistor is connected between the inverting input of the operating amplifier and low pass filter input.

The two-way limiter is made up of a module calculator, a peak detector, three operational amplifiers, an inverter, three resistors and two diodes, and the non-inverting input of the first operational amplifier and the input of the module calculator, the output of which is connected to the peak detector input, are connected in series to the second and the third resistors are connected between the output of the peak detector and the common bus, a non-inverting input of watt is connected to the common point of connection of the second and third resistors of the other operational amplifier and the inverter input, the output of which is connected to the non-inverting input of the third operational amplifier, while the inverting inputs of all operational amplifiers are connected to the output bus of the two-way limiter, to which one output of the third resistor, the anode of the first diode and the cathode of the second diode are also connected, a free output the third resistor, the cathode of the first diode and the anode of the second diode are connected to the outputs, respectively, of the first, second and third operational amplifiers.

The device is designed to generate a harmonic signal when a triangular waveform is input, the amplitude and frequency of which vary over a wide range, but is characterized by increased complexity.

The closest device to the claimed invention in terms of essential features is the multiplier of the frequency of quadrature signals [Dubrovin B.C., Zyuzin A.M. Frequency multiplier quadrature signals. Pat. Russian Federation No. 103993, Н03В 19/00. Application: 2010148151/09, 11/25/2010. Posted: 04/27/2011, Bull. No. 12], which contains the first and second dividers, a multiplier, a first and a second quadrator, a scaling amplifier, a subtractor, a first and second peak detectors, the first and second inputs of a frequency multiplier of quadrature signals connected, respectively, to the information inputs of the first and second dividers, the first and second inputs of the multiplier are connected, respectively, with the inputs of the first and second quadrators, the outputs of which are connected, respectively, the first and second inputs of the subtractor, the output of the multiplier is connected to the input of ma a amplifying amplifier, while the first and second outputs of the quadrature frequency multiplier are connected to the outputs of a scaling amplifier and subtracter, respectively, while the inputs of the first and second peak detectors are connected, respectively, to the first and second inputs of the quadrature frequency multiplier, and their outputs are with control inputs, respectively, of the first and second dividers, to the outputs of which the inputs of, respectively, of the first and second quadrators are connected.

The device is designed to generate two harmonic signals shifted by 90 electrical degrees relative to each other, and allows you to generate amplitude-stable signals with a frequency two times higher than the frequency of the input signals, and the amplitude values of the input signals can vary arbitrarily over wide limits, i.e. with their significant amplitude asymmetry.

The problem to which the invention is directed is to expand the functionality of the device and to obtain a harmonic signal with minimal nonlinear distortion at its output when a triangular waveform is input to the shaper inputs, the amplitude and frequency of which can vary over wide ranges and with significant asymmetry of the amplitudes of the input signals.

The technical result from the use of the proposed harmonic signal generator is to expand the functionality of the device and to obtain a harmonic signal with minimal nonlinear distortion when it is fed to the inputs of a triangular waveform generator, the amplitude and frequency of which can vary over wide ranges and with significant asymmetry of the amplitudes of the input signals .

The specified technical result is achieved by the fact that the harmonic signal former contains the first and second input buses, a two-channel amplitude stabilizer, a multiplier and a scaling amplifier, the input of which is connected to the output of the multiplier, the first and second inputs of which are connected to the corresponding outputs of the two-channel amplitude stabilizer, the first and the second inputs of which are connected, respectively, with the first and second input buses, an additional correction block is inserted, included between the output the amplifier and the output of the harmonic signal former, while the correction unit is made of the second and third multipliers and the adder, the first input of which is connected to the output of the third multiplier, the second input of which is connected to the second input of the adder, with the input of the correction unit, with the first and second inputs of the second multiplier, the output of which is connected to the first input of the third multiplier, and the output of the adder is connected to the output of the correction unit.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information, made it possible to establish that the applicant did not find an analogue characterized by features identical in all essential features of the claimed invention. Therefore, the claimed invention meets the condition of "novelty."

A distinctive feature of the present invention is the introduction of a correction unit into the device and the organization of new functional relationships between the elements, which made it possible to obtain a harmonic signal with minimal nonlinear distortions when it is fed to the inputs of a signal shaper of a triangular shape, the amplitude and frequency of which can vary over wide ranges and at significant asymmetry of the amplitudes of the input signals.

The invention is illustrated by the structural diagram of the harmonic signal generator (Fig. 1) and graphs (Fig. 2), explaining the principle of operation of the harmonic signal generator.

The harmonic signal generator (Fig. 1) contains a first 1 and second 2 input bus, a two-channel amplitude stabilizer 3, a multiplier 4, a scaling amplifier 5 and a correction block 6, connected between the output of the scaling amplifier 5 and the output of the harmonic signal former, while the correction block 6 made of the second 7 and third 8 multipliers and the adder 9, the first input of which is connected to the output of the third multiplier 8, the second input of which is connected to the second input of the adder 9, with the input of the correction unit 6, with the first and second direct inputs of the second multiplier 7, the output of which is connected to the first input of the third multiplier 8, and the output of the adder 9 is connected to the output of the correction unit 6.

The harmonic signal generator operates as follows.

The input buses 1 and 2 receive (Fig. 2, a) linearly changing signals V ₁ (t) and V ₂ (t), shifted relative to each other by 90 electrical degrees, the amplitude values of which L _1m and L _2m can have a significant amplitude asymmetry and bipolar deviations from the normalized value of A.

At the output of the two-channel amplitude stabilizer 3, amplitude-stable signals L ₁ (t) and L ₂ (t) are formed (Fig. 2, b).

To find the analytical expressions of the signals L ₁ (t) and L ₂ (t), we use the general expression for the straight line y = kx + b passing through two points with coordinates (x ₁ , y ₁ ) and (x ₂ , y ₂ )

where x is the current value of the angle in radians.

To simplify the argument, we assume that the amplitude values of the signals L ₁ (t) and L ₂ (t) are equal to the normalized value A ^* = 1.

Substituting in (1) the coordinates of the two boundary points [x ₁ = 0, y ₁ = 0; x ₂ = π / 2, y ₂ = 1], we obtain

Substituting in (1) the coordinates of two other boundary points [x ₁ = 0, y ₁ = 1; x ₂ = π / 2, y ₂ = 0] for the second section of the signal L (t), we obtain

As a result of multiplying the signals L ₁ (t) and L ₂ (t) at the output of the multiplier 4, a signal is generated

where m ₁ is the scale factor of the multiplier 4, which for simplification can be taken equal to unity.

The signal (Fig. 2, b) at the output of the scaling amplifier 5

where K is the gain of the scaling amplifier 5.

Analysis of the graphs (Fig. 2, a) shows that the extreme (maximum) value of the signal S (x) will correspond to the angle x ₀ = π / 4 (for the interval x∈ [0; π / 2]). Substituting the found value of x ₀ in equation (5), in which the maximum value of the signal S (x) will be equal to the normalized amplitude value A ^* = 1, we obtain

From equation (6) it follows that the necessary gain K = 4 provides a specified normalized value of the amplitude of the generated signal S (t) equal to unity.

Thus, at the output of amplifier 5, a quasi-harmonic signal S (t) is formed, the distortion coefficient of which, measured using the block (THD - Total harmonic distortion) of the PSIM 9 program, K _f1 = 3.746%.

To improve the spectral composition of the harmonic signal, a correction unit 6 is used, consisting of two quadrators 7, 8 and a multiplier 9.

The correction signal S _k (t) at the output of the third multiplier 8 (Fig. 2, c)

where m ₂ and m ₃ are scale factors, respectively, of the second 7 and third 8 multipliers.

When m ₂ = m ₃ = 1 we get

At the first input of the adder 9 receives a correction signal S _k (t), and at the second - a quasi-harmonic signal S (t). Thus, at the output of the adder 9, a signal is generated

where k ₁₁ and k ₁₂ are the transfer coefficients of the adder 9 on the first and second inputs, respectively.

When solving equations (5), (8) and (9) together, we obtain

In order to simplify, we introduce the following notation

For x = 0 and x = π / 2, the values of D (0) = D (π / 2) = 0, and for x = x _{0 the} value of D (x ₀ ) = D (π / 4) = 1/4.

The product K · D (x ₀ ) = 4 · (1/4) = 1, therefore, expression (10) can be greatly simplified

We set the amplitude of the signal N (x) equal to the normalized value A ^* = 1, then

Therefore, the coefficients k ₁₁ and k ₁₂ should be related by the following dependence

и

.Minimization of the harmonic coefficient occurs at optimal values

and

.

In this case, the distortion coefficient of the output signal N (t), measured using the block (THD - Total harmonic distortion) of the PSIM 9 program, K _f2 = 0.144%.

The efficiency of introducing the correction signal S _k (t) can be determined using the coefficient γ = K _f1 / K _f2 = 3,746 / 0,144 = 26, thus, the distortion of the output signal N (t) decreased by about 26 times.

Using the present invention will expand the functionality of the device and get its output a harmonic signal with minimal non-linear distortion when applied to the inputs of a triangular waveform shaper, the amplitude and frequency of which can vary over wide ranges and with significant amplitude asymmetry of the amplitudes of the input signals.

Claims (1)

A harmonic signal generator containing the first and second input buses, a two-channel amplitude stabilizer, a multiplier and a scaling amplifier, the input of which is connected to the output of the multiplier, the first and second inputs of which are connected to the corresponding outputs of the two-channel amplitude stabilizer, the first and second inputs of which are connected, respectively, with the first and second input buses, characterized in that it additionally introduced a correction unit included between the output of the scaling amplifier and the output the harmonic signal generator, the correction unit is made of the second and third multipliers and the adder, the first input of which is connected to the output of the third multiplier, the second input of which is connected to the second input of the adder, with the input of the correction unit, with the first and second inputs of the second multiplier, to the output which is connected to the first input of the third multiplier, and the output of the adder is connected to the output of the correction unit.

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