RU2230330C2 - Method establishing frequency - Google Patents

Abstract

FIELD: determination of carrier frequency and modulation form of signal received in specified frequency range. SUBSTANCE: device realizing proposed method includes receiving antenna, input circuit, search unit, high-frequency amplifier, heterodyne, mixer, intermediate frequency amplifier, detector, video amplifier, unit forming frequency scan, cathode-ray tube, two keys, five amplitude detectors, three high-pass filters, three low-pass filters, two squarers, two voltage dividers, frequency detector, spectrum analyzer, three comparators and phase detector. EFFECT: widened functional capabilities thanks to determination of modulation of form of received signal. 1 dwg

Description

The proposed method relates to the field of electronics and can be used to determine the carrier frequency and the type of modulation of signals received in a given frequency range.

Known methods for determining the frequency and devices for their implementation (ed. Certificate of the USSR No. 620907, 524138, 868614, 1000930, 1012152, 1180804, 1187095, 1272266, 1290192, 1354124; RF patent No. 2124216; US patent No. 4443801; Vakin S.A ., Shustov LN Fundamentals of Radio Countermeasures and Radio Engineering Intelligence (Moscow: Sov. Radio, 1968, p. 386-396, Fig. 10.3 and others).

Of the known methods, the closest to the proposed one is the “Search method for determining the frequency” (Vakin SA, Shustov LN Fundamentals of radio counteraction and electronic intelligence. M: Sov. Radio, 1968, p. 386-396, Fig. 10.3 ), which is selected as the base object.

The specified method provides the determination of only the carrier frequency of the received signal and does not allow to determine the type of modulation.

One of the characteristic features of modern and promising electronic equipment (RES) is the widespread use of simple and complex signals, which are characterized by a wide variety of modulations.

The type of modulation is an important characteristic of radio emissions, which provides a solution to a number of problems of reception and analysis of RES signals. The task of determining the type of modulation is also important in assessing the parameters of the modulating function of the received signals. Typically, parameter analyzers for each type of signal are constructed according to different principles and provide false information for signals with other modulation laws. Selection of signals by type of modulation makes it possible to eliminate this drawback.

An object of the invention is to expand the functionality of the method by determining the type of modulation of the received signal.

The problem is solved in that according to the method of determining the frequency, based on the search for signals in a given frequency range by tuning the superheterodyne receiver, forming a frequency sweep on the screen of the cathode ray tube, converting the frequency of the received signal, amplifying it by voltage, detecting and applying vertically tube deflecting plates, as a result of which a pulse is generated on the screen, by the position of which the carrier frequency of the received signal is determined on the frequency sweep a, determine the effective coefficient of amplitude modulation, the effective frequency deviation, the width of the spectrum of the received signal, the ratio of the width of the spectrum to the effective deviation of the frequency, compare them with certain numerical values and determine the amplitude or angular modulation of the received signal by angular modulation, frequency and phase detection of the received signal, determine the ratio of the amplitudes of the spectral components taken at the beginning of the frequency axis to the spectral amplitudes s components, taken at a certain distance from the axis, the resulting ratio is compared with the unit and the results of comparison, the frequency or phase modulation of the received signal.

The structural diagram of a device that implements the proposed method is presented in the drawing.

The device comprises serially connected receiving antenna 1, input circuit 2, high-frequency amplifier 4, mixer 6, the second input of which is connected to the local oscillator 5 output, intermediate-frequency amplifier 7, detector 8, video amplifier 9, and vertically deflecting plates of the cathode ray tube 11, horizontally deflecting plates which are connected to the device 10 forming a frequency sweep. The control inputs of the input circuit 2, the high-frequency amplifier 4, the local oscillator 5 and the frequency sweep forming device 10 are connected to the corresponding outputs of the search unit 3, for which a sawtooth voltage generator or an electric motor can be used. To the output of the high-frequency amplifier 4, a key 12 is connected in series, the second input of which is connected to the output of the detector 8, the amplitude detector 13, the high-pass filter 14, the first quadrator 16, the first voltage divider 17, the second input of which is connected to the output through the first low-pass filter 15 an amplitude detector 13, and a first comparison unit 23, the two outputs of which are the outputs of the device. A frequency detector 18, a second low-pass filter 19, a second quadrator 20 and a second voltage divider 22 are serially connected to the output of the key 12, the second input of which is connected through the spectrum analyzer 21 to the output of the key 12, and the output is connected to the second input of the first comparison unit 23. To the output of the key 12, a key 24 is connected in series, the second input of which is connected to the first output of the first comparison unit 23, a phase detector 25, a third low-pass filter 26, a second amplitude detector 28 and a second comparison unit 30, the second input of which is connected through a second filter 27 high frequencies and the third amplitude detector 29 is connected to the output of the phase detector 25, and two outputs are outputs of the device.

A third high-pass filter 32, a fifth amplitude detector 33 and a third comparison unit 34 are connected to the output of the frequency detector 18 in series, the second input of which is connected to the output of the low-pass filter 19 through the fourth amplitude detector 31, and the two outputs are outputs of the device.

The proposed method is implemented as follows.

The search for signals in a given frequency range is carried out using a search unit 3, which, according to a sawtooth law, consistently changes the settings of the input circuit 2, high-frequency amplifier 4 and local oscillator 5. At the same time, the search unit 3 controls the frequency sweep generation device 10 on the screen of the cathode ray tube 11.

The received signal after frequency conversion in the mixer 6 and amplification in the intermediate frequency amplifier 7, detection in the detector 9 and additional amplification in the video amplifier 9 is supplied to the vertically deflecting plates of the cathode ray tube 11, as a result of which a pulse is generated on the screen (frequency mark), whose position on the frequency sweep determines the carrier frequency of the received signal.

Modulated oscillation in its most general form can be written

Here, ω _s , φ _s is the carrier frequency and the initial phase of the oscillation;

where U _c is the amplitude of the carrier in the absence of modulation;

m is the coefficient of amplitude modulation;

Ω is the frequency of the modulating function.

For a signal with amplitude modulation (AM), expression (1) will have the form

If the AM signal is fed to the input of the amplitude detector 13 from the output of the high-frequency amplifier 4 through the public key 12, then a voltage is generated at its output

Therefore, the output of the amplitude detector 13 when exposed to its input of the AM signal is allocated a modulating function, which contains useful information.

If the input of the amplitude detector 13 receives a signal with angular modulation, then U (t) = U _c = const and expression (1) takes the form

those. U _AM (t) = U ₀ .

It can be seen from the obtained expressions that in the absence of a parasitic PA with amplitude modulation of the oscillation and parasitic AM with angular modulation of the oscillation, it is possible to distinguish the amplitude-modulated signal from the signal with angular modulation by passing it through the amplitude detector 13.

The following parameters can be used as informative signs of recognition of signals with amplitude and angular modulations:

- effective coefficient of amplitude modulation

- среднеквадратичное значение переменного напряжения сигнала и шума на нагрузке амплитудного детектора 13;Where

- the rms value of the alternating voltage of the signal and noise at the load of the amplitude detector 13;

M (t) = A (t) sinΩt is the modulating function;

- effective frequency deviation

where T is the duration of the signal;

- spectrum width Δω _{from the} received signal.

For the AM signal, these signs are equal to:

For the UM signal

The effective amplitude modulation coefficient m _eff is determined using an amplitude detector 13, a high-pass filter 14, a first low-pass filter 15, a first quad 16 and a first voltage divider 17.

The effective frequency deviation Δω _def is determined using a frequency detector 18, a second low-pass filter 19, a second quadrator 20 and a second voltage divider 22.

The width of the amplitude spectrum Δω _{from the} received signal is determined using the spectrum analyzer 21.

The ratio Δω _c / Δω _def is determined in the voltage divider 22. In the first comparison block 23, the measured values of m _eff and Δω _c / Δω _{def are} compared with certain numerical values of m ₀ and K ₀ . The comparison results determine the type of modulation (amplitude or angular) of the received signal.

If the received signal has angular modulation, then a constant voltage from the first output of the comparison unit 23 is supplied to the control input of the key 24, opening it. In the initial state, keys 12 and 24 are always closed. In this case, the received signal with angular modulation from the output of the high-frequency amplifier 4 through the public keys 12 and 24 is received for further processing.

It should be noted that the recognition of the type of angular (frequency or phase) modulation is a complex technical task. This is due to the difficulty of identifying informative features by which it is possible to distinguish a signal with frequency modulation (FM) from a signal with phase modulation (FM), since frequency and phase modulations, due to the integro-differential coupling between the frequency and phase, the oscillations have much in common with each other, which justifies the existence of the combined term “angular modulation”.

Note that due to this connection, frequency modulation is always accompanied by a change in the phase of the modulated oscillation, and when phase modulation is performed, there is always a change in the frequency of the radio signal. These changes are inextricably linked with each other, and the whole thing is which of them is primary, i.e. which one is proportional to the modulating function. With frequency modulation, obviously, the primary is the change in frequency, and with phase modulation is the change in the phase of high-frequency oscillations.

It should be noted that the recognition of FM and FM signals with a harmonic modulating function is generally impossible. However, real oscillations have a modulating function that is much more complex than harmonic. Therefore, there is a certain opportunity for the recognition of FM and FM signals using, as a sign of recognition, the deformation of the modulating function at the output of the frequency 18 and phase 25 detectors.

Let the expansion of the modulating function in a Fourier series on a certain time interval have the following form:

where U _i , Ω _i , φ _i - amplitude, frequency and initial phase of the i-th spectral component.

It is known that at the output of the phase detector 25, the oscillation phase will be distinguished

and at the output of the frequency detector 18, the differential from the phase is obtained

Consider the case when the type of detector corresponds to the type of angular modulation of the received signal.

For FM, ω (t) = M (t), Φ (t) = 0, and at the output of the frequency detector 18 we have

For FM, ω (t) = 0, Ф (t} = M (t), and at the output of the phase detector 25 we will have

If the type of detector does not match the type of angular modulation, then the following situations are possible.

Let the FM signal be input to the phase detector 25. Moreover, ω (t) = M (t), Ф (t) = 0 and at the output of the phase detector 25 we will have

Analyzing formula (11), we see that the spectrum of FM vibrations after phase detector 25 undergoes deformation. With increasing number of the spectral component, its amplitude will decrease, i.e. the ratio of the amplitudes of the spectral components taken at the beginning of the frequency axis to the amplitudes of the spectral components taken at a certain distance from the beginning of the axis will be more than 1.

Now we consider the passage of the FM oscillation through the frequency detector 18. For FM, ω (t) = 0, Ф (t) = M (t) and at the output of the frequency detector 18 we will have

From formula (12) it is seen that the spectrum of the FM vibration at the output of the frequency detector 18 also undergoes deformation. With an increase in the number of the spectral component, its amplitude will increase, i.e. the ratio of the amplitudes of the spectral components taken at the beginning of the frequency axis to the spectral components taken at a certain distance from the beginning of the axis will be less than 1.

The received FM signal from the output of the high-frequency amplifier 4 through the public keys 12 and 24 is fed to the inputs of the frequency 18 and phase 25 detectors. Low-pass filters 19 and 26 emit spectral components located at the beginning of the frequency axis. High-pass filters 27 and 32 emit spectral components located at some distance from the beginning of the axis. Amplitude detectors 28, 29, 31, and 33 extract the envelopes of the corresponding spectral components. Blocks 30, 34 of comparison determine the ratio of the amplitudes of the spectral components taken at the beginning of the frequency axis to the amplitudes of the spectral components taken at some distance from the beginning of the frequency axis at the outputs of the phase 25 and frequency 18 detectors. Depending on the specified relationship, a decision is made on the type of angular (frequency or phase) modulation of the received signal.

If the indicated ratio is greater than unity at the output of the phase detector 25, and the indicated ratio is approximately equal to unity at the output of the frequency detector 18, then the received signal has frequency modulation.

If at the output of the frequency detector 18 the ratio of the amplitudes of the spectral components taken at the beginning of the frequency axis to the spectral components taken at some distance from the beginning of the axis is less than unity, and at the output of the phase detector 25 it is approximately equal to one, then the received signal has phase modulation.

Thus, the proposed method in comparison with the prototype provides a definition of not only the carrier frequency of the received signal, but also the type of modulation. Thus, the functionality of the method is expanded.

Claims (1)

A method for determining the frequency based on the search for a signal in a given frequency range by tuning the superheterodyne receiver, forming a frequency sweep on the cathode ray tube screen, converting the received signal in frequency, amplifying it in voltage, detecting and applying to the tube vertically deflecting plates, as a result of a pulse is generated on the screen, by the position of which the carrier frequency of the received signal is determined on the frequency sweep, characterized in that the effective coefficient is determined ient amplitude modulation, the effective frequency deviation, the width of the spectrum of the received signal, the spectrum ratio of the width to the effective frequency deviation is compared effective coefficient of an amplitude modulation and a spectrum width ratio to the effective frequency deviation with specific numerical values and determine the amplitude or angle-modulated received signal according to the following criteria: for amplitude modulation

where m _eff is the effective coefficient of amplitude modulation;

- the ratio of the width of the spectrum to the effective frequency deviation, for angular modulation m _eff ≥ m _o ; m _o

2 ÷ 3;

when angular modulation, frequency and phase detection of the received signal is carried out, the ratio of the amplitudes of the spectral components taken at the beginning of the frequency axis is determined to the amplitudes of the spectral components taken at a certain distance from the beginning of the axis, the obtained ratio is compared with unity, if this ratio is greater than one, conclude about the frequency modulation of the received signal, if less - about the phase.