RU82868U1 - DEVICE FOR RADIO TECHNICAL CONTROL OF SOURCES OF RADIO RADIATION - Google Patents

Abstract

A device for radio-technical control of sources of radio emission, comprising a first receiving antenna, a high-frequency amplifier, a power divider, a frequency meter and a unit for processing results of measurements and bearing calculation, a second receiving antenna and a second high-frequency amplifier connected to a third receiving antenna, a third amplifier high frequency and the first phase difference meter, the second input of which is connected to the second output of the power divider, and the output is with the second input of the unit for processing the results of measurements and calculation of the bearing, while the focal axes of the receiving antennas are parallel and coincide in the direction to the center of the direction-finding sector, characterized in that a second phase difference meter is introduced into it, the first input of which is connected to the output of the second high-frequency amplifier , the second - with the third output of the power divider, and the output - with the third input of the processing unit of the measurement results and bearing calculation, while the processing unit of the measurement results and bearing calculation is performed t re-input, and the rough value of значениеГ bearing is calculated by the formula! ! where λ, is the wavelength of the controlled signal; ! a is the distance between the focal centers of the first and second receiving antennas; ! Δφ is the phase difference of the controlled signal at the outputs of these antennas.

Description

The utility model relates to radio engineering and can be used to determine the bearing and frequency of a radio signal in radio control systems.

A device for radio-technical control of sources of radio emissions is known, which is part of the information-measuring system for monitoring sources of radio emissions, described in the article by E.V. Chekrygin and others. "Information-measuring system for monitoring sources of radio emissions" [Questions of special radio electronics. Issue 1. - Moscow - Taganrog. TNIIIS.- 2003.] It contains M receiving antennas, M direction finding channels, each of which consists of a series-connected high-frequency amplifier (UHF), an amplitude detector and a logarithmic video amplifier, and a unit for processing measurement and control results.

The signs of this analogue, which coincide with the essential features of the claimed utility model, are three receiving antennas, three UHF and a unit for processing measurement results.

The disadvantage of this device is the low direction finding accuracy due to the amplitude direction finding method and the non-identical antenna patterns.

There is also known a device for radio-technical control of radio emission sources, which is part of a shipborne radio intelligence station protected by a utility model certificate No. 29783, class. G01S 3/28, H04K 3/00, publ. 2003, it contains M≥4 receiving antennas, M UHF, the inputs of which are connected to the outputs of the antennas, M dividers

power, the inputs of which are connected to the outputs of the UHF, M receivers, the inputs of which are connected to the first outputs of the power dividers, a frequency meter, M inputs of which are connected to the second outputs of the power dividers, a bearing finder and a unit for processing measurement and control results, the first M inputs of which are connected to the outputs of the receivers, the (M + 1) th and (M + 2) th inputs - with the first and second outputs of the frequency meter, (M + 3) th input - with the output of the bearing finder, and the output - with the control input of the bearing finder . In this case, the bearing qualifier contains M pairs of additional receiving antennas, two switches, the control inputs of which are combined and are the control input of the qualifier, and an interferometer, the output of which is the output of the qualifier. The focal axes of the receiving antennas are shifted relative to one another so that their radiation patterns in total overlap the 180 ° sector of the ship's left (or star) side.

The signs of this analogue, which coincide with the essential features of the claimed utility model, as in the analogue described above, are three receiving antennas, three UHF, and a processing unit for measuring results.

In this device, the results of measuring the direction to the radiation source are refined by introducing 2M additional antennas, which makes the device quite complex and difficult to implement. In addition, the direction finding accuracy in it remains insufficiently high, which is due to the non-identity of the additional antennas and the lack of refinement of the bearing in the "feed - bow" directions of the ship and the opposite.

The closest in technical essence to the claimed utility model (prototype) is a device for radio control of radio emission sources according to the patent of the Russian Federation No. 2316016 class. G01S 3/28, 2005. It contains in series a first receiving antenna, a first UHF, a first power divider, a frequency meter and a processing unit

results of measurements for bearing and control calculation, the second receiving antenna, the second UHF and the second power divider, the third receiving antenna, the third UHF and the phase difference meter, the second input of which is connected to the second output of the first power divider, and the output to the second the input of the processing unit of the measurement results for bearing calculation and control, the first multiplier connected in series, the first input of which is connected to the third output of the first power divider, and ne a low-pass filter, the output of which is connected to the third input of the measurement results processing unit for calculating the bearing and control, the second multiplier connected in series, the first and second inputs of which are connected respectively to the first and second outputs of the second power divider, and the second low-pass filter, the output is which is connected to the fourth input of the processing unit for measuring results for bearing and control calculation, and a controlled phase shifter, the signal input of which is connected to the third output of the second division power amplifier, control input - with the output of the processing unit for measuring results for bearing and control calculation, and the output - with the second input of the first multiplier. In this case, the focal axis of the antennas are parallel and coincide in direction with the direction to the center of the direction-finding sector.

Signs of the prototype, which coincides with the essential features of the claimed utility model, are three receiving antennas, three UHF, a power divider, a frequency meter, a phase difference meter and a unit for processing measurement results and bearing calculation.

The disadvantage of this device is the complexity and relatively low reliability, which is due to the presence of multipliers, low-pass filters, a controlled phase shifter and a rather complex four-input processing unit for the measurement results, which performs both the bearing calculation function and the phase shifter control function.

The task to which the creation of a utility model is directed is to simplify the device and increase its reliability.

To achieve a technical result, in a known device for radio-technical control of radio emission sources, comprising a first receiving antenna, a first UHF, a power divider, a frequency meter and a unit for processing measurement results and bearing calculation, a second receiving antenna and a second UHF connected in series with a third receiving antenna , the third UHF and the first phase difference meter, the second input of which is connected to the second output of the power divider, and the output to the second the second unit of the phase difference, the first input of which is connected to the output of the second UHF, the second to the third output of the power divider, is introduced to the unit of processing the results of measurements and bearing calculation, while the focal axes of the receiving antennas are parallel and coincide in direction with the direction to the center of the direction-finding sector. and the output - with the third input of the unit for processing the measurement results and bearing calculation, while the processing unit for the measurement results and bearing calculation is made three-input, and the rough value значение _{Г of the} bearing is calculated by the formula:

where λ is the wavelength of the controlled signal;

a is the distance between the focal centers of the first and second receiving antennas;

Δφ is the phase difference of the controlled signal at the outputs of these antennas.

The totality of the newly introduced meter of the phase difference, relationships, features of the unit for processing the measurement results and bearing calculation and changes to the rough bearing estimation algorithm should not be explicitly from the prior art, therefore, the proposed device for radio-technical control of radio emission sources should be considered new.

The essence of the utility model is illustrated in the drawing, which shows:

figure 1 is a structural diagram of the proposed utility model;

figure 2 - the relative position of the source of the controlled radio emission and the centers of the aperture of the antennas.

The utility model contains identical receiving antennas 1, 2 and 3, identical to UHF 4, 5 and 6, phase difference meters 7 and 8, power divider 9, frequency meter 10 and unit 11 for processing measurement results and bearing calculation.

Antenna 1, UHF 4 and meter 7 are connected in series. Antenna 2, UHF 5, divider 9 and meter 10 are connected in series. Antenna 3, UHF 6 and meter 8 are connected in series. The second and third outputs of the divider 9 are connected to the second inputs of the meters 8 and 7, respectively. The first, second and third inputs of block 11 are connected to the outputs of the meters 10, 8 and 7, respectively.

The centers of the aperture of antennas 1, 2 and 3 are located on one straight line, and the focal axes are parallel to each other and perpendicular to this straight line, their 2-O ′ direction coincides with the direction of the axis of symmetry of the direction-finding sector (Fig. 2). Bearing Θ (direction to the source of radio emission) is counted from the direction 2-O ′ clockwise. The width of the radiation pattern of each of the antennas 1, 2 and 3 is 180 °. The linear base a between the centers of the aperture of antennas 1 and 2 is about 0.25λ _min , and the linear base b between the centers of the aperture of antennas 2 and 3 is about 10λ _min , where λ _min is the minimum wavelength of the direction-finding signal.

The utility model uses the phase direction finding method based on the reception of the direction-finding signal by two antennas with parallel focal axes and spaced aperture centers and subsequent measurement of the phase difference of the received signals. It is known (see, for example, Leonov A.I., Fomichev K.I. Monopulse radar.- M. Sov. Radio,

1984, p.6, 7), that in this case the phase difference Δφ of the received signals is related to the bearing θ of the signal source, its length λ, wave and base d between the centers of the aperture of the antennas by the ratio

The utility model is as follows. The emitted radio signal to be monitored is received by antennas 1, 2 and 3 and amplified by amplifiers 4, 5 and 6, respectively. From the outputs of the amplifier 5, the amplified signal is fed to the input of the divider 9, which divides the signal received at its input into three equal parts arriving at its outputs.

The signal from the first output of the divider 9 is fed to the input of the meter 10, the signal from its second output is sent to the second input of the meter 8, and the signal from its third output is sent to the second input of the meter 7. At the first inputs of meters 7 and 8, signals from the outputs of amplifiers 4 and 6, respectively.

The meter 10 measures the frequency f of the monitored signal, and the measurement result is received from its output at the first input of block 11.

The meter 8 measures the phase difference Δφ _{1 of the} signals at its inputs, and the measurement result from its output goes to the second input of block 11.

Similarly, the meter 7 measures the phase difference Δφ of the signals at its inputs, and the measurement result from its output goes to the third input of block 11.

Block 11 converts the signals arriving at its inputs into a digital form suitable for performing mathematical operations on them (in principle, the signals at the inputs of meters 7, 8, and 10 can be analog or digital, but do not coincide in bitness or type of code with the waveform, used directly in block 11).

In addition, block 11 performs a number of mathematical operations on the converted signals, which will be discussed below.

The frequency f received at the first input of block 11 is used to calculate the length λ, the wave of the signal being monitored. The calculation is made in block 11 according to the formula

where c = 3 · 10 ⁸ m / s is the speed of light.

The obtained value of λ, together with the value Δφ of the phase difference of the signals received by antennas 1 and 2, is used for a rough estimate of bearing Θ. The rough value Θ _{Г of the} bearing, taking into account equation (1), is determined by calculating in block 11 by the formula

The calculation according to formula (2) gives the value of the true bearing Θ with a large error due to the non-identity of the channels for generating signals at the inputs of the meter 7 and the error in measuring the phase difference Δφ.

To clarify bearing Θ, the phase difference of the signals at the outputs of antennas 2 and 3, measured by meter 8, is used, the value Δφ _{1 of} which comes from the output of meter 8 to the second input of block 11.

The phase difference Δφ _1ph , the signals at the outputs of the antennas 8 and 14 will be

Given that the base is b = 10λ _min , it can significantly (at times) exceed 2π. The meter 8 does not respond to the integer part of the ratio Δφ _1ph / 2π, but measures only the remainder of the division Δφ _1ph . by 2π. The actual Δφ _1ph and the measured Δφ ₁ phase differences are related by

Δφ _1ph = Δφ ₁ + 2πn,

where n = 0, ± 1, ± 2, ..., ± m, and m is the integer part of the ratio b / λ.

Therefore, equation (3) should be written as

Equation (4) contains uncertainty - one value of the measured phase difference Δφ corresponds to 2m + 1 bearing values Θ. To resolve this uncertainty in block 11, all these values are calculated in accordance with equation (4), then all or part of them are compared with the value Θ _G calculated by formula (2), and the nearest one is taken as the result of direction finding.

The inventive utility model is quite easy to implement.

As antennas 1, 2, and 3, slotted antennas can be used in a limited-size screen (see, for example, the Handbook on the elements of electronic devices. Edited by V.V.Dulin, M.S.Zhuk. - M.:

Energy. - 1977, p. 528, 529).

As amplifiers 4, 5, and 6, commercially available M421135 type modules can be used.

As meters 7 and 8, phase detectors of the FIFK type with analog outputs can be used.

The power divider 9 can be made on the basis of passive microassemblies.

The meter 10 can be performed on single-resonator directional filters with functional processing of the responses of the output signals on programmable logic integrated circuits (see, for example, E.V. Chekrygin and others. "Information and measuring system of radio emission sources." Questions of special radio electronics. OVR series. - Moscow - Taganrog, issue 1. - 2003, p. 7 ... 14).

As a block 11, a Pentium-type personal computer can be used, supplemented by interface elements with meters 7, 8, and 10.

The technical result from the use of the proposed utility model is that it is simpler than the prototype, since it does not contain multipliers, filters, and a controlled phase shifter. The processing unit of the measurement results in the claimed utility model is simpler than in the prototype. It has fewer inputs, and the control function is excluded in it. The greater simplicity of the utility model provides it with higher reliability. An approximate calculation shows that the mean time between failures of the claimed utility model is approximately 10% more than that of the prototype.

Claims (1)

A device for radio-technical control of sources of radio emission, comprising a first receiving antenna, a high-frequency amplifier, a power divider, a frequency meter and a unit for processing results of measurements and bearing calculation, a second receiving antenna and a second high-frequency amplifier connected to a third receiving antenna, a third amplifier high frequency and the first phase difference meter, the second input of which is connected to the second output of the power divider, and the output the second input of the unit for processing the results of measurements and calculation of the bearing, while the focal axes of the receiving antennas are parallel and coincide in the direction to the center of the direction-finding sector, characterized in that a second phase difference meter is introduced into it, the first input of which is connected to the output of the second high-frequency amplifier , the second - with the third output of the power divider, and the output - with the third input of the processing unit of the measurement results and bearing calculation, while the processing unit of the measurement results and bearing calculation is performed t re-input, and the rough value груб _{Г of the} bearing is calculated by the formula

where λ, is the wavelength of the controlled signal; a is the distance between the focal centers of the first and second receiving antennas; Δφ is the phase difference of the controlled signal at the outputs of these antennas.