RU192626U1 - MODULATOR FOR COMPLEX SIGNAL - Google Patents

Abstract

The utility model relates to functional signal converters and can be used in coherent complex signal processing systems for transferring to a high frequency spectrum a low-frequency complex signal defined by a pair of quadrature components. The technical result achieved by the implementation of the claimed utility model is to expand the frequency range of the low-frequency modulating signal The modulator for the complex signal includes a balanced modulator, a second balanced modulator, a subtraction unit and a 90-degree phase shifter. The technical result achieved is achieved by using two balanced modulators in the modulator for a complex signal for separate processing of the material and imaginary components of a low-frequency modulating signal, followed by subtracting the output signals of these balanced modulators. Introduction of an additional balanced modulator for processing the imaginary component complex low-frequency modulating signal allows you to not only highlight in the output signal one working spectral region, but at the same time suppress the spectral component with the frequency of the modulated high-frequency oscillation and the second non-working spectral region, thereby expanding the frequency range of the low-frequency modulating signal.

Description

The utility model relates to functional signal converters and can be used in coherent processing systems of complex signals for transferring to a high frequency spectrum of a low-frequency complex signal specified by a pair of quadrature components:

where u _x (t), u _y (t) are the real and imaginary components of the complex signal; U (t), ϕ (t), Ω is its amplitude, initial phase, and average frequency, which can take both positive and negative values.

The result of modulation is a high-frequency oscillation of the form

where ω ₀ , ϕ ₀ is the frequency and initial phase of the modulated high-frequency harmonic oscillation; k is the coefficient of proportionality.

The signal u _m (t) represents only one spectral region at a frequency ω = ω ₀ + Ω in the spectrum of a modulated high-frequency oscillation. The frequency of the low-frequency modulating signal Ω. can vary widely with respect to the frequency ω _{0 of the} modulated high-frequency oscillation.

Known basic modulator based on a nonlinear element (transistor) (B.K. Suprun, V.I. Khilenko. Radio transmitting and receiving devices and measuring their parameters. M: Publishing house standard, 1988. P. 83, Fig. 6.11).

The modulator is designed for amplitude modulation of high-frequency harmonic oscillations by a low-frequency signal. The modulator contains an amplifying stage on a transistor with a load in the form of a resonant oscillatory circuit tuned to a frequency ω _{0 of a} modulated high-frequency harmonic oscillation. In this case, the base of the transistor is at the same time an input for both a high-frequency modulated harmonic oscillation and a low-frequency modulating signal.

As a result, a signal of the form

which does not match the required signal (1).

Thus, a comparison of relations (1) and (2) implies that the disadvantage of the modulator under consideration is the presence in the output signal instead of one of two side spectral regions at frequencies ω ₁ = ω ₀ + Ω, ω ₂ = ω ₀ -Ω and the spectral component at a frequency ω = ω ₀ .

A well-known balanced modulator (B.K. Suprun, V.I. Khilenko. Radio transmitting and receiving devices and measuring their parameters. M: Publishing house standard, 1988. P. 92, Fig. 6.20).

The balance modulator is designed for amplitude modulation of high-frequency harmonic oscillations by a low-frequency signal with suppression in the output signal spectrum of a component with a frequency ω _{0 of} modulated high-frequency harmonic oscillations.

The balance modulator contains two inputs. The first input is an input for a high-frequency modulated harmonic oscillation, the second is an input for a low-frequency modulating signal.

As a result, a signal of the form

which does not match the required signal (1).

Thus, from a comparison of relations (1) and (4), it follows that the disadvantage of the modulator under consideration is the presence in the output signal instead of one of two side spectral regions at frequencies ω ₁ = ω ₀ + Ω and ω ₂ = ω ₀ -Ω.

The closest in technical essence to the proposed utility model is a modulator (AN Pakhvalyan. Radio transmitting devices. M: "Communication", 1967. P. 386, Fig. 12.6).

The modulator is designed for amplitude modulation of high-frequency harmonic oscillation with a low-frequency signal while simultaneously suppressing in the output signal spectrum a component with frequency ω _{0 of} modulated high-frequency harmonic oscillation and one side spectral region with an average frequency of ω ₀ -Ω.

The modulator contains a balanced modulator and a filter for allocating a side spectral region with an average frequency of ω ₀ + Ω, the output of a balanced modulator is connected to the input of a filter for allocating a side spectral region, the first input of a balanced modulator is an input for high-frequency modulated harmonic oscillation, and the second is an input for low-frequency modulating signal.

At the output of the modulator, a signal of the form

which in shape corresponds to the desired signal (1).

However, for simultaneous effective suppression of the spectral component with the frequency ω ₀ and the spectral region with the average frequency ω ₀ -Ω in the modulator output signal, it is necessary that the lower frequency of the filter passband substantially exceed the value of the frequency ω _{0 of the} high-frequency modulated oscillation, which limits the range of possible changes in the frequency Ω low frequency modulating signal.

Thus, the disadvantage of the modulator under consideration is the limited frequency range Ω of the low-frequency modulating signal.

The main task, which the utility model aims to solve, is to create a modulator for a complex signal with a wide frequency range Ω of the low-frequency modulating signal.

The technical result achieved by the implementation of the claimed utility model is to expand the frequency range of the low-frequency modulating signal.

The specified technical result is achieved in that the modulator for the complex signal, including a balanced modulator, the first input of which is the input for modulated high-frequency harmonic oscillation, and the second is the input for the real component of the low-frequency complex modulating signal, further comprises a second balanced modulator; subtraction unit and phase shifter 90 degrees; the input of which is connected to the first input of the first balanced modulator; the phase shifter output is 90 degrees connected to the first input of the second balanced modulator; the output of the first balanced modulator is connected to the first input of the subtraction unit; the output of the second balanced modulator is connected to the second input of the subtraction unit, the output of which is the output of the modulator for the complex signal; the second input of the second balanced modulator is an input for the imaginary component of the low-frequency complex modulating signal.

The stated technical result is achieved by introducing additional blocks and connections between them into the modulator for the complex signal, which allows organizing an additional processing channel for the imaginary component of the complex low-frequency modulating signal and thereby not only highlighting one spectral region with an average frequency ω ₀ + in the modulator output signal Ω, but at the same time suppress the spectral component with frequency © o of the modulated high-frequency oscillation and the spectral region from the middle frequency -Ω minutes ω _0, and thus extend the range of frequency variation of the modulating low frequency signal.

The analysis of the prior art by the applicant has established that the analogues lack a set of features identical to those of the claimed utility model “Modulator for a complex signal”. Therefore, the claimed utility model meets the condition of "novelty."

The search results for known technical solutions in this and related fields of technology in order to identify features that match the distinctive features of the claimed utility model have shown that they do not follow explicitly from the prior art.

The essence of the utility model is illustrated by the drawing, where in FIG. 1 shows a modulator for a complex signal.

Modulator for complex signal, including balanced modulator 1; second balanced modulator 2; subtraction unit 3 and phase shifter 90 degrees 4; the input of the phase shifter 90 degrees 4 is connected to the first input of the first balanced modulator 1; the output of the phase shifter 90 degrees 4 is connected to the first input of the second balanced modulator 2; the output of the first balanced modulator 1 is connected to the first input of the subtraction unit 3; the output of the second balanced modulator 2 is connected to the second input of the subtraction unit 3; the input of the phase shifter 90 degrees 4 is the input for modulated high-frequency harmonic oscillation; the second input of the first balanced modulator 1 is an input for the real component of the low-frequency complex modulating signal; the second input of the second balanced modulator 2 is an input for the imaginary component of the low-frequency complex modulating signal; the output of the subtraction block 3 is the output of the modulator for the complex signal.

Balanced modulators are made on the basis of four semiconductor diodes of the D9 type and two high-frequency transformers containing ferrite rings and windings from an insulated copper wire.

An upset oscillatory circuit is used as a 90 degree phase shifter.

As a subtraction unit, a high-frequency transformer with on-off windings.

The modulator for the complex signal operates as follows.

At the input of the phase shifter 90 degrees 4 receives a high-frequency harmonic oscillation u ₀ (t) = U ₀ cos [ω ₀ t + ϕ ₀ ]. As a result, at its output, a high-frequency harmonic oscillation u ₀ (t) = U ₀ sin [ω ₀ t + ϕ ₀ ] is shifted in phase by 90 degrees. When simultaneously applying to the first input of the first balanced modulator 1 a high-frequency harmonic oscillation u ₀ (t) = U ₀ cos [ω ₀ t + ϕ ₀ ] and to the second input, the real component of the modulating low-frequency complex signal u _x (t) = U (t ) cos [Ωt + ϕ (t)] at the output of the first balanced modulator 1, a high-frequency signal of the form u _bm1 (t) = U ₀ U (t) cos [Ωt + ϕ (t)] cos [ω ₀ t + ϕ ₀ ] is generated . At the same time, from the phase shifter output 90 degrees 4, a high-frequency harmonic oscillation u ₀ (t) = U ₀ sin [ω ₀ t + ϕ ₀ ] is fed to the first input of the second balanced modulator 2, and the imaginary component of the modulating low-frequency complex signal u _{y is} applied to the second input (t) = U (t) sin [Ωt + ϕ (t)]. In this case, the output of the second balanced modulator 2 produces a high-frequency signal of the form u _bm2 (t) = U ₀ U (t) sin [Ωt + ϕ (t)] sin [ω ₀ t + ϕ ₀ ]. As a result of subtraction in the subtraction unit 3 of the output signals of the first balanced modulator 1 and the second balanced modulator 2, the output signal of the balanced modulator for the complex signal is generated according to the rule

This signal contains only one side spectral region at a frequency ω = ω ₀ + Ω. In this case, the frequency Ω of the low-frequency modulating signal can vary over a wide range, assuming both positive and negative values.

A comparison of the parameters characterizing the claimed utility model and the prototype allows us to conclude that the claimed utility model provides the transfer of the spectrum of the modulating low-frequency complex signal to the frequency of the modulated high-frequency harmonic oscillation, the spectrum of which contains only one side spectral region with the possibility of changing over a wide frequency range modulating signal.

The above information proves that the following conditions are fulfilled when implementing the claimed model:

- the tool embodying the proposed utility model in its implementation is intended for use in coherent processing systems of complex signals for transferring the spectrum of a low-frequency complex signal to the frequency of a modulated high-frequency harmonic oscillation, the spectrum of which would contain only one side spectral region with the possibility of changing over a wide frequency range modulating signal;

- for the claimed utility model in the form described in the independent clause of the utility model formula, the possibility of its implementation using the means described before the filing date of the application is confirmed;

- a tool that embodies the claimed utility model in its implementation, is able to provide the specified technical result.

Therefore, the claimed utility model meets the condition of "industrial applicability".

Claims (1)

A modulator for a complex signal, including a balanced modulator, the first input of which is an input for a modulated high-frequency harmonic oscillation, and the second is an input for the real component of a low-frequency complex modulating signal, characterized in that the device further comprises a second balanced modulator, a subtraction unit and a 90-degree phase shifter whose input is connected to the first input of the first balanced modulator; the phase shifter output is 90 degrees connected to the first input of the second balanced modulator, the output of the first balanced modulator is connected to the first input of the subtraction unit, the output of the second balanced modulator is connected to the second input of the subtraction unit, the output of which is the modulator output for the complex signal; the second input of the second balanced modulator is an input for the imaginary component of the low-frequency complex modulating signal.

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