RU2483317C2 - Apparatus for measuring scattering cross-section of large-size objects - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: apparatus for measuring scattering cross-section (SCS) of large-size objects, having series-connected pulsed transmitter, antenna switch, antenna, receiver and computer, the second input of which is connected to a control panel, the second input/output of which is connected to the main rotary support on which the measured object is placed, the third input/output of the control panel is connected to an additional rotary support at whose centre there is a SCS metre, which is in form of a triangular angle reflector, wherein the additional rotary support is mounted on a linear displacement device which is connected to the fourth input/output of the control panel, wherein the additional rotary support is placed between the main rotary support and the transmitter in the same pulsed volume with the measured object.

EFFECT: high accuracy of measuring SCS of large-size objects in the decimetre and metre wavelength range.

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Description

The invention relates to radar, in particular to radar measurements, and can be used on open radio measuring ranges.

Measurements of the effective scattering area (EPR) at open radio measuring ranges are characterized by a large amount of preparatory work, one of which is the installation of the object on a rotary support device, which is located in the measuring volume. At the same time, during measurements it is necessary to remove the measured object from the measuring volume and replace it with a reference reflector (ESR measure) for calibration. The frequency of calibration is determined by the metrological characteristics of the measuring complex and to achieve the required accuracy of the measurement results, there should be no more than the interval of long-term instability of the parameters of the measuring equipment of the complex. However, for some types of full-sized large-scale objects that do not have the ability to autonomously maneuver (hereinafter referred to as large-sized objects), the time required to complete the replacement procedure with a reference reflector and then reinstall the object on a rotary platform significantly exceeds the long-term instability interval of the main metrological characteristics of the complex’s measuring equipment, which leads to to increase the measurement error.

The well-known RAT SCAT complex for measuring radar cross-sectional targets [Marlow, Watson and Van Hozer. RAT SCAT complex for measuring radar cross-section of targets. TIIER, 1965, t. 53, No. 8, p. 1085].

The RAT SCAT complex contains a pulse transmitter, an antenna switch, an antenna, a rotary support device, an object of measurement, a reference reflector, a receiver, a computer, a control panel, and the pulse transmitter is connected to the input of the antenna switch, the output of which is connected to the antenna input, the second output of the antenna the switch is connected to the receiver, the output of which is connected to the input of the calculator, the second input of the calculator is connected to the slewing device.

EPR measurements using the RAT SCAT complex are performed as follows. Initially, the equipment is calibrated. The calibration procedure is as follows: the EPR of a retractable reference reflector relative to the sphere is measured; To maintain calibration during the measurement process, this reflector is installed in a resolution cell in a range different from the one in which the object to be measured is located.

The installation of a reference reflector in another range resolution cell leads to measurement errors due to different background levels at the location of the object and the reference reflector.

The closest in technical essence is a device for measuring the effective scattering area of large objects [Russia, Patent 2308043, G01S 13/00, 2007], which contains a series-connected pulse transmitter, antenna switch, antenna, receiver and calculator, to the second input of which a control panel is connected, the second input-output of which is connected to the main slewing ring, on which the measured object is located, and the third input-output of the control panel is connected to the additional reference an o-rotary device on which a measure of the effective scattering area is eccentrically established, wherein an additional rotary support device is located between the main rotary support device and the transmitter in the same pulsed volume with the measured object.

The value of the distance R on, which can be taken as a measure of the EPR from the center of the additional slewing ring, is determined by the condition:

R≥λ / Δφ,

where λ is the wavelength, Δφ is the analysis sector.

This condition is determined by the following consideration that at least two periods of electromagnetic wave oscillations should fit within the analysis sector Δφ. Only in this case, the measurement error does not exceed 0.5 dB.

For example, with λ = 3 cm and Δφ = 0.1 rad, the magnitude of the ESR removal distance from the center of the additional slewing ring will be R = 30 cm, which is acceptable for the measurements.

At λ = 30 cm and Δφ = 0.1 rad, the magnitude of the distance of the ESR removal from the center of the additional slewing ring will be R = 3 m.

When λ = 3 m and Δφ = 0.1 rad, the distance of the ESR measure removal from the center of the additional slewing ring will be R = 30 m.

The given example clearly illustrates the impossibility of using this device for the decimeter and meter wavelength ranges. With increasing wavelength, if you do not increase the distance the ESR measure is taken away from the center of the additional rotary support device, the measurement error will increase. And if you increase the distance of the removal of the EPR measure from the center of the additional slewing ring by tens of meters, this will lead to the impossibility of implementing such a device.

The disadvantage of this device is that its use in the decimeter will lead to large errors in the measurement of the EPR of objects, and in the meter wavelength range such a device is generally not feasible.

Thus, the technical task is to increase the accuracy of the EPR measurement of large-sized objects in the decimeter and meter wavelength ranges.

A new technical result is achieved due to the fact that in the known device for measuring the EPR of large-sized objects, containing serially connected pulse transmitter, antenna switch, antenna, receiver and calculator, the second input of which is connected to the control panel, the second input-output of which is connected to the main reference - a rotary device on which the measured object is placed, and the third input-output of the control panel is connected to an additional rotary support device on which it is installed as a measure of the effective scattering area, with the additional rotary support device located between the main rotary support device and the transmitter in the same pulsed volume as the measured object, a linear displacement device has been introduced, onto which an additional rotary support device is installed, in the center of which the effective area measure is placed scattering, made in the form of a trihedral angular reflector, in addition, the linear displacement device is connected to the fourth input-output of the control panel Nia.

Let us explain the essence of the proposed technical solution.

In the claimed technical solution for the calibration, a linear displacement device is used, on which an additional rotary support device is installed. In this case, a measure of the effective scattering area is made in the form of a trihedral angular reflector, which is placed in the center of an additional slewing ring. As ESR measures for the long-wavelength part of the range, it is preferable to use trihedral angular reflectors, characterized by a wide backscatter pattern and high ESR.

To carry out linear movement of the additional slewing ring along the line “antenna - main slewing ring” it is placed on the linear displacement device, which is connected to the fourth input-output of the control panel.

The analysis of the prior art allows us to establish that the inventive device, characterized by a combination of features identical to all the features contained in the claims proposed by the applicant, is absent, which indicates compliance of the claimed invention with the criterion of "novelty".

The search results for known solutions in this and related fields of technology in order to identify features that match the excellent features of the claimed device showed that no solutions having features matching its distinctive features, namely the additional introduction of a linear displacement device, were found in publicly available information sources. on which an additional rotary support device is installed, in the center of which a measure of the effective scattering area is made, made in the form of a trihedral angular reflector, in addition, the linear displacement device is connected to the fourth input-output of the control panel. The prior art also does not confirm the popularity of the influence of the distinctive features of the claimed device on the technical task - improving the accuracy of measuring large objects in the decimeter and meter wavelength range, therefore, the claimed invention meets the condition of "inventive step".

The invention "A device for measuring the EPR of large-sized objects" is industrially applicable, since the combination of characteristics characterizing it, provides the possibility of its implementation, performance and reproducibility for measuring the EPR of large-sized objects in the decimeter and meter wavelength ranges, since known devices can be used to implement materials and equipment.

The figure shows a device for measuring the effective dispersion area of large objects. A device for measuring the EPR of large-sized objects consists of a pulse transmitter - 1, an antenna switch - 2, an antenna - 3, a main rotary support device - 4, a measured object - 5, an additional rotary support device - 6, effective scattering area measures - 7, linear displacement devices - 8, control panel - 9, computer - 10, receiver - 11.

The pulse transmitter is 1, the antenna switch is 2, the antenna is 3, the receiver is 11, and the computer is 10 connected in series. The measured object - 5 is installed on the main rotary support device - 4, the measure of the effective scattering area is made in the form of a trihedral angular reflector - 7 and is installed in the center of the additional rotary support device - 6, which is placed on the linear displacement device - 8. Control panel - 9, the first output is connected to the computer - 10, the second input-output is connected to the main rotary support device - 4, the third input-output of the control panel - 9 is connected to the additional rotary support device - 6, fourth control panel input-output - 9 connected to a linear displacement device.

A device for measuring the EPR of large objects works as follows. The measured object - 5 is installed on the main rotary support device - 4. From the control panel - 9, the pulse transmitter - 1 and the main rotary support device - 4. are simultaneously turned on. The pulse transmitter - 1 through the antenna switch - 2 and the antenna -3 emits a signal direction of the measured object - 5. in this case, the measured object - the platform 5 rotates on main slewing device - a receiver 4. - 11 receives reflected signals from the object of measurement - 5 (P _n) in total turnover rotary platfor s 360 degrees and are supplied to the calculator - 10. Simultaneously with this on the computer - 10 from the main slewing device - 4 comes information about the measuring object angle φ - 5, to thereby obtain a pie chart object EPR power. After that, the measured object continues to rotate - 5 until the power level of the reflected signal from it is approximately equal to the power level of the signal from the EPR measure R _et , and this value is known and obtained by calculation.

Then the additional rotary support device - 10 is placed on the linear displacement device - 8, and the ESR measure is set in the center of the additional rotary support device - 6, made in the form of a trihedral angular reflector - 7 with the known ESR σ _et . From the control panel - 9, simultaneously turn on the rotation of the additional slewing ring device - 6 and the linear displacement device - 8. Then, using the receiver - 11, the reflected signals are received and fed to the computer - 10, where the maximum signal P _max reflected from the EPR measure is determined - 7. Use receiver - 11 registers the power level of the vector sum of signals reflected from the object to be measured - 5 and rotating the ESR measures - 7, and fed to the calculator - 10, where the selected maximum P _max P _min and minimum level values m generality reflected signals, whereby the ESR is determined at the point of interaction of the measured object - with a measure ESR 5 - 7 according to the formula

This formula is obtained by solving the system of equations (2) and (3) for the interaction of two reflectors

After that, from the control panel - 9, the rotation of the additional rotary support device - 6 and the linear displacement device - 8 are simultaneously turned off. The additional rotary support device - 6 with an EPR measure - 7 and the linear displacement device - 8 are removed from the irradiation zone (working volume) . A point at an object with an EPR σ _{b is} used as a reference. And then the calculator - 10 calculates the ESR of the measured object - 5 for any angle φ, using the ESR at the point of interaction σ _vz and the interaction power P _vz , according to the formula

The use of the claimed device can improve the accuracy of the EPR measurement of large objects in the decimeter and meter wavelength range.

Claims (1)

A device for measuring the effective dispersion area of large-sized objects, containing a pulse transmitter, an antenna switch, an antenna, a receiver, and a computer connected in series, to the second input of which a control panel is connected, the second input-output of which is connected to the main rotary support device on which the measured object is located and the third input-output of the control panel is connected to an additional rotary support device on which a measure of the effective scattering area is set, at the additional rotary support device is located between the main rotary support device and the transmitter in the same pulsed volume with the measured object, characterized in that a linear displacement device along the line “antenna - main rotary support device” is inserted into it, on which the additional support - a rotary device, in the center of which is placed a measure of the effective scattering area, made in the form of a trihedral angular reflector, in addition, a linear displacement device dineno to the fourth input-output control unit.

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