RU2311651C1 - Rotary device for measuring amplitude diagrams of reverse dissipation of large dimension objects - Google Patents

Abstract

FIELD: radiolocation.

SUBSTANCE: in accordance to the invention, on a round platform, meant for placement of large-dimensional object, supported by air cushion or vertical shaft, mounted in a well of foundation, at its center a metallic area in form of truncated cone, closed on top, is rigidly held at its center. Height of area is determined from formula H_ar0,71(H_ob-H_ch), where H_ob, H_ch - height of object and height of its wheel chassis. Diameter of upper part of area equals diameter of platform, and diameter of lower part - D_{ar l} = D_{ar u} + 2H_arctgα, where D_{ar u} - diameter of upper part of area and α - inclination angle of cone generatrix.

EFFECT: increased precision when measuring reverse dissipation diagrams of large dimension objects near underlying surface in millimeter-decimeter wave length ranges with simultaneous expansion of area of usage of device.

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Description

The invention relates to the field of radar, in particular to radar measurements of one of the main radar characteristics - amplitude backscatter patterns (DOR) of radar targets such as aircraft, helicopter, car with kung, etc. on open landfills.

By definition, the DOR of a radar object is the dependence of the parameters (amplitude, phase) of the radar signal (PC) reflected from the object when its spatial position relative to the measuring radar changes according to a given law. As a rule, the amplitude DOR of a large-sized object at open-type polygons is measured during its rotation in a circle in the azimuthal plane in the wavelength ranges from millimeter to meter.

The proposed device is intended for instrumentation of measurements of amplitude DOR of moving large-sized objects with a base size of up to 10 m, a height of 6-10 m and a weight of several tens of tons. It is such radar targets that create the greatest difficulties in measuring their DOR with the required accuracy for the following main reasons [1. E.A. Stager. Scattering of radio waves by complex bodies. - M .: Radio and communications, 1986, p.171-174; 2.R.B.Dibdal. Methods for measuring the effective reflection area of radar targets. - TIIER, 1987, t.75, No. 4, p.81-99]:

1. The requirements for the mechanical strength and carrying capacity of most known devices for rotating the targets in question contradict the standard conditions for smooth rotation of the target and the low level of the probing PCs reflected from the device;

2. The relatively large (up to 6-10 m) sizes of the targets in the vertical plane, their placement in the far zone of the location near the underlying surface (PP) significantly complicate the uniformity of the irradiating field strength along the opening of the target in the vertical plane and reduce the accuracy of the DOR measurements;

3. Large sizes of radar targets such as aircraft (up to 20-25 m or more in the horizontal plane) lead to significant re-reflections of the PC between the known slewing ring and the lower part of the target, which leads to additional errors in measuring their DOR.

Several large-capacity devices are known for turning large-sized and long objects. For example, a stand for a turn of the plane [3. Russia, AC 364505, IPC B64f 1/24, 1972], a device for ground turning of an airplane [4. Russia, AS 473643, IPC B64f 1/24, 1975], slewing ring [5. Russia, AC 2092424, IPC 6 В66С 23/84, 1997].

A common disadvantage of the known devices is the low accuracy of measuring the amplitude DOR of large-sized objects when they are placed on known devices due to the high level of interference PCs reflected (or re-reflected when interacting with the object) by such a device, as well as due to the significant irregularity of the irradiation field strength by opening the object in vertical plane. The main sources of such irregularity of the irradiating field when measuring the amplitude DOR of large objects at landfills with shielding PP and with radar screens (RLE), respectively, are [1. E.A. Stager. Scattering of radio waves by complex bodies. - M .: Radio and communications, 1986, p.171-174; 2.R.B.Dibdal. Methods for measuring the effective reflection area of radar targets. - TIIER, 1987, t.75, No. 4, p.81-99]:

the interaction of direct probing PCs with specularly reflected from the PP in the working volume of the radar where the object is located;

disturbance in the significant propagation zone of direct probing PCs introduced by the RLE, as well as diffraction of the latter by the RLE.

Closest to the proposed device in technical essence and achieved the main positive effect is a device for ground turn of the aircraft [4. Russia, AC 473643, IPC B64f 1/24, 1975], comprising a platform equipped with a cantilever platform for the nose landing gear and supported by an air cushion, and a vertical shaft mounted in the foundation well by bearings. In order to increase the reliability of operation (including smooth rotation of the aircraft), a cylindrical board is fixed on the lower surface of the platform, located in the annular channel formed in the foundation, which is filled with a liquid that insulates the air from the external environment.

The main disadvantages of the prototype, which lead to low accuracy in measuring DOR of large objects, especially at landfills with shielding PP, are:

the impossibility of lifting the object in question to a height sufficient (with its specified dimensions) to ensure uniformity of the intensity of the irradiating field in its opening in a vertical plane;

high level of interfering PC at the input of the measuring radar, due to the re-reflection of the probing signals in the "lower part of the object - platform" system.

The technical task of the present invention is to improve the accuracy of measuring the amplitude DOR of large objects near the PP in the millimeter - decimeter wavelength ranges, as well as expanding the scope of the device.

The solution to this problem is achieved due to the fact that the composition of the prototype containing the platform, equipped with a cylindrical side fixed on its lower part, located in the annular channel of the foundation, filled with liquid with low viscosity and low freezing temperature, and supported by an air cushion created by compressed air , and a vertical shaft installed in the foundation well by means of bearings, as well as a platform rotation drive, are introduced: a platform rotation angle meter sensor, rigidly fixed about the center of the upper part of the platform, a metal platform in the form of a truncated cone, the diameter of the upper part of which is equal to the diameter of the platform in the horizontal plane, and the height and diameter of the lower part are determined by the formulas, respectively:

where H and H _{about brs} - the height of the object and the height thereof wheeled undercarriage _(brs H ≡0 for land-based mobile machinery)

and

where D _{PL in} - the diameter of the upper part of the site, determined taking into account the maximum dimensions of the base of the moving object in the horizontal plane;

N _PL - the height of the site, determined according to (1);

α is the angle of inclination of the generatrix of the cone (α = 45 °), determined taking into account the need to exclude the influence of interference PCs reflected from the side surface of the cone on the measurement results of the object DOR.

In addition, to reduce the level of interfering PCs caused by the re-reflection of the probing signals in the "site - lower part of the system" system, the upper part of the site is covered by broadband radar absorbing material (RPM).

Equation (1) is obtained in accordance with the well-known expression [1. E.A. Stager. Scattering of radio waves by complex bodies. - M .: Radio and communication, 1986, p.173] for the function of attenuating the intensity (amplitude) of the irradiating field by opening an object in a vertical plane:

where V is the function of attenuating the intensity (amplitude) of the irradiating field;

h - the current value of the height of the opening of the object in a vertical plane;

h ₀ - the height of the Central part of the aperture of the object in this plane,

with an acceptable value of the decrease in the intensity of the irradiating field at the lower and upper boundaries of the aperture of the object (not more than 1dB) [6. R.G. Kuyumjan, L. Peters. Distance requirements for radar cross-section measurements. TIIER, 1965, t. 53, No. 8, p. 1057-1066].

и знак (-) угла места, под которым может происходить зондирование площадки в вертикальной плоскости, а также - размеры площадки, определяемые в соответствии с соотношениями (1)-(2).The value of the angle of inclination α of the side surface of the site was chosen equal to 45 ° as a sufficient condition to exclude the influence of PC reflected from this surface on the results of measuring the DOR of the object. In this case, the width of the main DOR lobe of the generatrix of the truncated cone (platform) for the maximum radiation wavelength of the measuring radar (λ = 1 m) was taken into account, the maximum value

and the sign (-) of the elevation angle at which sounding of the site in the vertical plane can occur, as well as the dimensions of the site, determined in accordance with relations (1) - (2).

Equation (2) is obtained on the basis of simple geometric relations for a truncated cone.

A comparative analysis of the claimed invention with the prototype shows that the proposed device differs from the known by the presence of new features, including:

new elements - a metal platform rigidly fixed in the center of the platform in the form of a truncated cone, broadband radio-absorbing material placed on its outer surface, and a sensor for measuring the platform angle of rotation;

new characteristics - a significant (20-25 dB) decrease in the level of background PCs reflected (reflected) from the device’s platform and the lower part of the object in the direction of the measuring radar; the ability to compare the current values of the object DOR with its angular position in the azimuthal plane; the relative uniformity of the intensity of the irradiating field over the opening of the object in a vertical plane.

The use of new elements of the claimed device (a metal support in the form of a truncated cone, broadband RPM, a sensor for measuring the angle of rotation of the platform) and the implementation of the known principles for achieving relative uniformity of the irradiating field by opening the object in a vertical plane (based on its rise to a certain height), and also - reducing the level of jamming PCs (based on the choice of a special form of the site, its minimum size and the use of broadband radio-absorbing material) allow significantly increase the accuracy of measuring the amplitude DOR of the objects under consideration.

A quantitative assessment of increasing the accuracy of measuring the amplitude DOR by ensuring the uniformity of the irradiating field over the opening of the object in a vertical plane depends on its geometric dimensions and design. So, for example, for an object 8 m high relative to the PP with a wheel chassis height of 1.4 m, the decrease in the intensity of the irradiating field according to (3) is 0.55 compared to its central part. However, in this case, the accuracy of the results of measuring the amplitude DOR is unsatisfactory, since the root mean square value of the partial measurement error is 39%. In the case of placing the object in question on the proposed device with a platform height of N _PL = 4.7 m, determined according to (1), the rms value of the considered measurement error of the amplitude DOR does not exceed 11% and practically does not affect the resulting accuracy of its measurement [7. E.N. Mayzels, V.A. Torgovanov. Measurement of scattering characteristics of radar targets, p.188-200. Publishing house "Soviet Radio", M., 1972].

The analysis of the prior art in the field of radar measurements and related areas made it possible to establish that technical solutions characterized by a combination of features identical to those contained in the claims proposed by the applicant are absent, which indicates compliance of the claimed invention with the “novelty” protection criterion.

The results of the search for known solutions in the field of radar measurements and related technical fields in order to identify features that match the distinctive features of the claimed device showed that in publicly available sources of information solutions that have features matching the distinctive features of the latter have not been identified. When analyzing the prior art, the popularity of the analytical dependence of the influence of the distinctive features of the present invention on the technical result indicated by the applicant is not confirmed, therefore, the present invention meets the condition of "inventive step".

The proposed technical solution is industrially applicable, and the combination of characteristics characterizing it provides the possibility of execution, operability and reproducibility, since known materials and equipment can be used to implement the claimed solution.

The figure shows a functional diagram of the claimed device in working position with the object and the main components of a typical radar measuring complex (RIC).

The device comprises a platform 2 installed on the foundation 1, equipped with a metal platform 3 in the form of a truncated cone for the wheeled chassis of the object 4 and supported by an air cushion created in the cavity A by compressed air, and a vertical shaft 5 located in the well 6 by means of bearings 7, and on the foundation 1 with supports 8 in the initial (inoperative) state. The platform 2 is mechanically coupled to the platform rotation drive 9, and a cylindrical board 10 is mounted on its lower surface, located in the annular channel B formed in the foundation 1, which is filled with liquid to seal the gap in it to prevent air leakage. The outer side of platform 3 is covered by broadband RPM (11). A sensor 12 is mounted on the shaft 5 of the platform angle measuring device 13. The inventive device (similar to the measuring radar 14, recording device 15, and the platform 2 angle measuring device 13) is included as a main component in a typical radar measuring complex (RIC).

Improving the accuracy of the results of measuring the amplitude DOR of large-sized objects using the proposed device is achieved by ensuring the uniformity of the irradiating field in the opening of the object in the vertical plane, almost completely eliminating the influence of jamming PCs (reflected) from the device and monitoring the platform rotation angle. The proposed device, in addition, allows you to expand the list of types (classes) of tested objects, the amplitude DOR of which are to be measured, due to the more universal (compared to the prototype) site and the ability to place objects at an adequate height.

The rotary device for measuring the amplitude DOR of large objects works as follows.

The operation of the inventive device begins after a report on the readiness for operation of all components of the RIC, when placing the test object 4 on the site 3, closing its outer surface with broadband RPM 11 (for example, type "Pile") and the command "Enable rotation of the platform 2" (for example , via cable lines) to the meter 13 of the angular position of the platform and then to the recording device 15.

The probing signals of the measuring radar 14 at a fixed frequency of a certain polarization are reflected from the object 4 and fed to the receiving device of the radar 14, from the output of which they are transmitted to the recording device 15. The recording device 15 provides graphs of the circular amplitude DOR of the object at a given frequency. In the case of multi-frequency measuring radar 14, the sounding of the object 4 located on the site 3 of the device occurs almost simultaneously. In this case, the recording device 15 provides graphs of circular amplitude DOR of object 4 for several frequencies of the probing signals of a certain polarization.

Reflected from the site 3, closed by broadband RPM 11, the radar signals attenuate to 20-25 dB and are partially reflected from its side surface in a direction other than the vector "site 3 - antenna of the measuring radar 14". Radar signals repeatedly reflected in the "lower surface of object 4 — platform 3 with RPM 11" system, as well as signals reflected from the side surface of platform 3, have no practical effect on reducing the accuracy of measuring the amplitude DOR of object 4.

Claims (1)

A rotary device for measuring amplitude patterns of backscattering of large-sized objects in the azimuthal plane, comprising a platform equipped with a cylindrical side fixed on its lower part, located in the annular channel of the foundation, filled with a liquid with low viscosity and low freezing temperature, and resting in the working position on an air cushion created by compressed air and on a vertical shaft mounted in the foundation well through bearings, as well as a platform turning drive s, characterized in that on the vertical shaft of the device there is a sensor for measuring the angle of rotation of the platform, made in the form of a circle, and a metal platform in the form of a truncated cone, the diameter of the upper part of which is equal to the diameter of the platform, is rigidly fixed and covered with broadband radio-absorbing material in its center the height and diameter of the lower part are determined by the formulas: N _pl = 0.71 · (N _rev- N _cs ) and D _{pl n} = D _{pl in} + 2H _pl · ctg α, respectively, where H _rev and H _cs are the height of the object and its a wheeled chassis _(brs H = 0 for objects ground movably art) D _{Space in} - diameter of the upper part of the site, α - angle of the cone.