RU2713865C1 - Amplitude-modulated signal demodulation method - Google Patents

Abstract

FIELD: radio engineering and communication.

SUBSTANCE: invention relates to processing of amplitude-modulated radio signals. Method for processing an amplitude-modulated radio signal comprising an upper sideband region and a lower sideband region, characterized in that amplitude-frequency composition of difference frequencies of signals in side frequency regions relative to carrier frequency of demodulated signal is picked up and summed up at coincidence of amplitudes equal to difference frequencies relative to carrier frequency, thus forming in proper amplitude-time domain proper demodulated signal.

EFFECT: technical result of disclosed invention consists in increase in information transmission efficiency, which contributes to expansion of technical capabilities of electronic devices.

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Description

FIELD OF THE INVENTION

The present invention relates to the processing of amplitude-modulated radio signals, in particular to methods and devices for demodulating amplitude-modulated radio signals including their selection, which is widely used in analysis technology of recovery and encryption of transmitted information.

State of the art

Traditional methods and devices for the demodulation of amplitude-modulated signals (AMC) consist of the following operations. From the source, the AMS is fed to a non-linear element, with its help, the AMC spectrum is destroyed into high-frequency and low-frequency components. Using a low-pass filter (low-pass filter), low-frequency components of the oscillation are isolated, the amplitude of which varies according to the law of change of the AMS envelope. Using the separation capacitance included in the longitudinal circuit, the constant component is eliminated and the low-frequency variable component is supplied to the load.

Such methods include the method (patent RU 2373631) of amplitude demodulation of amplitude-modulated radio frequency signals in which the problem of noise immunity and increasing the working frequency band is solved by optimizing the input four-terminal network, which is responsible for the amplitude modulation depth and, additionally, by optimizing the location of the non-linear element

The disadvantage of the proposed method is the inability to separate signals in the conditions of partial or complete overlap of the frequency bands of signal propagation.

The known method (patent RU 2342772) for processing an amplitude-modulated signal comprising a region of an upper sideband and a region of a lower sideband of a demodulated signal, in which by using the operation of weighing the demodulated areas of the sidebands, taking into account the noise power in the selectable reception bandwidth, is formed as a prototype. demodulated upper sideband signal and demodulated lower sideband signal, followed by summing the generated weighted demodulated signals fishing sideband signal to form a demodulated. In the method, the signal processing occurs in narrow frequency ranges, which allows for each pair of mirror bands to use its own weight coefficient.

The disadvantage of this method is the inability to effectively process signals in the conditions of partial or complete overlap of the frequency bands of signal propagation. If it is necessary to transmit several arbitrary analog signals with mutual partial or complete overlapping of their frequency bands, the separation of signals becomes extremely difficult.

The aim of the invention is to develop a method with increased transmission efficiency, reception selection and analysis of the received information in the conditions of use for the transmission of signals of combined frequency bands.

The technical result achieved during the implementation of the method is to increase the performance of information transfer, which helps to expand the technical capabilities of electronic devices created by the application of this method.

SUMMARY OF THE INVENTION

The technical result is achieved by the fact that they implement a method for processing an amplitude-modulated radio signal containing a region of the upper sideband and a region of the lower sideband, characterized in that the amplitude-frequency composition of the difference frequencies of the signals in the side frequency regions relative to the carrier frequency of the demodulated signal is selected and matched amplitudes of equal difference frequencies relative to the carrier frequency, forming a demodulated signal in the amplitude-time domain.

The use of amplitude-modulated radio frequencies of each signal with its own carrier frequency forms on the air symmetric regions of the amplitude-frequency composition of each signal with its side bands relative to its carrier frequency. A comparison of the frequency regions of the signals, taking into account their symmetry with respect to their carrier frequency, can make it possible to identify exactly the amplitude-frequency composition of the signal, the sum of which will be the demodulated signal.

Analysis of the upper and lower frequency bands of the demodulated signal allows you to identify the amplitude-frequency composition of each of the side bands and compare them taking into account their "mirror" - the equality of the difference frequencies and amplitudes relative to the carrier frequency. When the amplitudes of equal difference frequencies coincide, the signals are summed, thus forming a demodulated signal in the amplitude-time domain.

The amplitude-modulated single-tone signal has the form:

a _am (t) = A ₀ ⋅ [1 + m⋅cos (Ω⋅t + ϕ)] ⋅cos (ω ₀ ⋅t), Ω << ω ₀

where: A ₀ is the amplitude of the carrier oscillation, Ω is the frequency of single-tone amplitude modulation, ϕ is the initial phase of single-tone modulation, ω ₀ is the modulated frequency is the carrier, m is the amplitude modulation coefficient, the values of which lie in the range 0≤m≤1.

The amplitude-modulated single-tone signal also has the form:

a _am (t) = A ₀ ⋅cos (ω ₀ ⋅t) + 0.5⋅A ₀ ⋅m⋅cos [(ω ₀ -Ω) ⋅t-ϕ] + 0.5⋅A ₀ ⋅m⋅cos [(ω ₀ + Ω) ⋅t + ϕ]

The generated signal consists of three harmonics: the central one with frequency ω ₀ , offset by the upper frequency (ω ₀ + Ω), lower frequency (ω ₀ -Ω) relative to ω ₀ . Thus, a single-amplitude amplitude-modulated oscillation occupies a 2Ω band. In this case, the difference frequencies in the sidebands will be equal to Ω, and the amplitude of the difference frequencies will be 0.5⋅A ₀ ⋅m.

Each harmonic of the initial spectrum gives rise to lower and upper side mirror harmonics. The harmonics of an arbitrary signal will behave similarly to a single-tone signal with the remark that the frequencies of these harmonics will be mirror with respect to ω ₀ and shifted to the upper band by frequencies [ω ₀ + Ω _n (t)] and to the lower band by frequencies [ω ₀ -Ω _n ( t)]. The amplitudes of the harmonics will be mA ₀ K _n (t) / 2, respectively, representing the "instantaneous spectrum" of an arbitrary signal. Where: n is a natural number corresponding to the harmonic number of an arbitrary signal, K _n (t) is a coefficient reflecting the magnitude of the amplitude of the harmonic with a frequency [ω ₀ -Ω _n (t)] and a harmonic with a frequency [ω ₀ + Ω _n (t)] . In this representation, the difference frequencies will be equal to Ω _n (t).

The modern approach to compressing the amount of transmitted information on the air under conditions of a limited width of the allowed band of radio signals relies on the complication of modulation of the carrier frequency while ensuring the absence of frequencies of other signals on the used frequency band of the ether for the time of signal transmission (time-frequency separation).

Using the property of an amplitude-modulated radio signal: its mirror frequency composition, forming side frequency bands relative to the carrier frequency, can make it possible to isolate the amplitude-modulated radio signal in the used frequency band without freeing it from other signals. This will allow you to compact the amount of information transmitted in this frequency band for a certain period of time.

It should be noted that the coincidence of the frequency composition of arbitrary signals in the selected frequency band is not constant in time and the allocation of the harmonic composition of the signals can be made dynamic - through the formation of the "instant spectrum". This is possible because after digital filtering, FIG. 1, “instantaneous” frequencies with their amplitudes mA ₀ K _n (t) / 2, FIG. 2, each signal occupies its active band of the frequency spectrum as a function of time at its carrier frequency.

(Fink L. M. “Signals of the interference of error ...” M: Radio and communication, 1984; Kharkevich A. “Spectra and analysis” M .: Book house “LIBROKOM”, 2009).

In more detail, the proposed method will be described below when describing the operation of the device for implementing the proposed method.

A brief description of the figures of the drawings.

In FIG. 1 shows a block diagram of a method.

In FIG. 2 shows the amplitude-frequency composition of the signal.

The proposed method includes an analog-to-digital Converter - ADC, item 1; digital filters of difference frequencies of the upper band - ЦФВП1, ..., ЦФВПn, pos. 2, 4 ,; digital filters of difference frequencies of the lower band - ЦФНП1, ..., ЦФНПn, pos. 3, 5; peak detectors-comparators, pos. 6, 7; difference frequency generators Ω ₁ , ..., Ω _n , pos. 8, 9; harmonic combiner of difference frequencies, pos. 10; digital-to-analog signal converter, pos. eleven.

The implementation of the invention:

When implementing the method of processing the amplitude-modulated signal, the following sequence of actions is performed. The set of radio signals is fed to the ADC, pos. 1. The converted digital sequence from the ADC is fed to the narrow-band digital filters TsFVP1, ..., TsFVPn, pos. 2, 4 and TsFNP1, ..., TsFNPn, pos. 3 and 5, the frequency bands of which comprise a continuous frequency band of the existence of the signal, and frequency division by bands determines the resolution of the decomposition of the signal.

The frequency bands of the filters CFVP1, ..., CFVPn and TsFNP1, ..., TsFNPn are grouped in pairs with mirror symmetry relative to the carrier frequency of the desired signal.

A digital sequence from each mirror pair of filters is fed to a digital peak detector-comparator of the current amplitudes, pos. 6, 7. If the amplitudes from the filter pair coincide, the magnitude of these amplitudes is fed to the difference frequency generator of the filter pair, pos. 6, 7 to control the amplitude of this frequency. The supply of synthesized oscillations to the adder, pos. 10 is carried out by the same detector-comparator, pos. 6, 7 from the moment of detecting the coincidence of the amplitudes for a period not less than the period of this difference frequency. The values of peak amplitudes in the detector-comparators are updated after half the periods of the signals from the corresponding bandpass filters. The total signal, if necessary, have its analog form, is fed to the DAC, pos. eleven.

Claims (1)

A method for processing an amplitude-modulated radio signal containing a region of the upper sideband and a region of the lower sideband, characterized in that for the demodulation of the signal, the amplitude-frequency composition of the difference frequencies of the signals in the side frequency regions relative to the carrier frequency of the demodulated signal is extracted and the amplitudes of equal difference frequencies coincide relative to the carrier frequency, forming a demodulated signal in the amplitude-time domain.

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