RU2564659C1 - Radar measurement system - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: radar measurement system includes series-connected receiver, computer, pulse transmitter, antenna switch and antenna, wherein the second output of the antenna switch is connected to the input of the receiver; the system also includes a rotary support with the measurement object placed in a measurement volume, and a control panel which is connected by the first, second and third outputs to the second input of the transmitter, the input of the rotary device and the second input of the computer, respectively; the computer is also connected by the third input to the output of the rotary device; the system also includes a radar-absorbent device installed on the measurement path at a certain distance from the antenna.

EFFECT: high accuracy of measuring the radar cross-section diagram of objects.

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Description

The invention relates to radar, in particular to radar measurements of the effective scattering area (EPR) of objects, and can be used in open radio measuring ranges.

Known pulse measuring installation [E.N. Meisels, V.A. Merchants. Measuring the dispersion characteristics of radar targets. - M .: Soviet radio. - 1972, 166 S.], containing a pulse transmitter, a transmitting antenna, a receiving antenna, a receiver, a control panel, a goniometer, a rotary device, a support, a diffuser and a recording device.

A disadvantage of the known device is the low accuracy of measurements of the EPR diagram of objects, which is due to the influence of specular reflection of the irradiating electromagnetic field from the underlying surface on the formation of the resulting amplitude-phase distribution of the electromagnetic field in the measuring volume and background reflection from elements located behind the object in the pulsed volume.

The closest in technical essence is a complex for measuring radar cross-section of targets [Marlow, Watson and Van Hozer. RAT SCAT complex for measuring radar cross-section of targets. TIIER, 1965, v. 53, No. 8, p. 1085].

The complex contains a series-connected receiver, calculator, pulse transmitter, antenna switch and antenna, while the second output of the antenna switch is connected to the input of the receiver, as well as a rotary support device with a measured object located in the measuring volume and a control panel, which is the first, second and the third outputs are connected to the second input of the transmitter, the input of the rotary device and the second input of the computer, respectively, in addition, the computer is connected by the third input to the output of the th device.

The device does not provide for eliminating the influence of specular reflection of the irradiating electromagnetic field from the underlying surface on the formation of the resulting amplitude-phase distribution of the electromagnetic field in the measuring volume and background reflection from elements located behind the object in the pulsed volume, which leads to low accuracy of measurements of the EPR diagram of the objects.

The technical result of this invention is to increase the accuracy of measurements of the EPR diagram of objects by eliminating the influence of a specularly reflected irradiating electromagnetic field from the underlying surface on the formation of the resulting amplitude-phase distribution of the electromagnetic field in the measuring volume and background reflection from elements located behind the object in the pulsed volume.

The specified technical result is achieved due to the fact that in the known device containing a series-connected receiver, calculator, pulse transmitter, antenna switch and antenna, the second output of the antenna switch is connected to the input of the receiver, as well as a rotary support device with a measured object placed in the measuring volume and the control panel, which is connected by the first, second and third outputs to the second input of the transmitter, the input of the rotary device and the second input of the calculator, respectively Accordingly, in addition, the third input computer is connected to the output of the rotary device, the profile of the measuring path is inclined, while the rotary support device with the measured object is located at the upper point of the measuring path, and the antenna is located at the bottom, in addition, a radar absorbing device is inserted into it installed on the measuring path at a distance from the antenna, which is determined by the formula

,

,

where H _A is the height of the phase center of the antenna above the horizontal plane, R is the distance between the phase center of the antenna and the vertical axis passing through the center of the measuring volume, D _P is the size of the measuring volume in depth, α is the angle of inclination of the profile of the measuring path to the horizontal, H ₀ - height of the lower boundary of the measurement volume with respect to the horizontal plane, H _P - size of the measuring volume adjustment, wherein the width of the radio device is selected at least the minor axis length of the ellipse of the first antenna Fresnel zone and height op edelyayut formula

.

.

The invention is illustrated by the figure, which shows the relative position of the elements of the radar measuring complex. The figure shows: antenna - 1, the phase center of which is located at a height of N _And above the horizontal plane; slewing-rotary device - 2, located in the "far zone"; the measured object - 3, located in the measuring volume - 4 with dimensions: H ₀ - the height of the lower boundary of the measuring volume relative to the horizontal plane, N _P - the size of the measuring volume in height and D _P - the size of the measuring volume in depth; radar absorbing device - 5, α is the angle of inclination of the measuring path profile to the horizontal, in addition, the geometry of the rays along which the energy of the irradiating field is distributed is shown schematically: A - direct, B - mirror reflected from the underlying surface of the measuring path and in the absence of a radar absorbing device falling into the upper point of the measuring volume closest to the antenna, B - a straight line passing through the edge of the radar absorbing device and falling into the lower point of the measuring volume farthest from the antenna.

To measure the effective scattering area of objects with high accuracy, it is necessary that the object is irradiated with an electromagnetic field with a uniform amplitude-phase distribution over its surface, that is, the object must be in the measuring (working) volume with a uniform amplitude-phase distribution. This is achieved for an object that is located no closer than the “far zone” of the antenna [Zakharyev L.N., Lemansky A.A., Turchin V.I., Tseitlin N.M., Scheglov K.S. Methods for measuring the characteristics of microwave antennas. - M .: Radio and communications, 1984, p. 8] and is irradiated only with a direct beam. However, on surface paths, due to the multipath nature of the propagation of radio waves, the resulting amplitude-phase distribution of the electromagnetic field in the measuring volume of the complex is determined by the interference of direct and specularly reflected rays from the underlying surface. In addition, the level of background reflection from elements (unevenness of the underlying surface, vegetation, poles, various structures, etc.) located behind the object in the pulsed volume of the radar measuring complex has a significant impact on the measurement accuracy.

The invention improves the accuracy of measurements by eliminating the influence on the measurement results of both factors by making the profile of the measuring path of the radar measuring complex inclined and placing the slewing ring with the measured object at the upper point of the measuring path, the antenna at the bottom, and also by placing on measuring path of the radar absorbing device in the selected place and of certain sizes.

The following requirements are imposed on a radar absorbing device: it must not obscure the measuring volume of the radar measuring complex from irradiating electromagnetic waves propagating directly from the antenna (beam A), and should prevent the electromagnetic waves radiated by the antenna and reflected from the underlying surface from entering the measuring volume of the radar measuring complex. (beam B).

The size and location of the radar absorbing device on the measuring path should be determined as follows.

The width of the radar absorbing device is chosen not less than the length of the small axis of the ellipse of the first Fresnel zone of the antenna on the underlying surface. Provided that the minimum height of the measuring volume of the radar measuring complex is greater than the height of the phase center of the HA antenna (to exclude reflections from track elements beyond the working volume), the radar absorbing device should not cross the path of the direct beam from the antenna to the far lower point of the measuring volume (beam B )

Based on this condition, the radar absorbing device should be installed in a certain place of the measuring path so that the upper edge of the radar absorbing device touches the beam B. In this case, taking into account the inclined profile of the measuring path, the further the radar absorbing device is located, the lower the height it will have.

From the geometric relationships, it is possible to unambiguously determine the distance from the antenna to the radar absorbing device R _E and its height H _E , at which the beam of the antenna mirror reflected from the underlying surface is overlapped, up to the straight line connecting the point of specular reflection of the beam and the point of the measuring volume closest to the antenna with the maximum height (beam B) and the radar absorbing device will have the lowest possible height.

In the case when the underlying surface is flat, inclined to the horizon at an angle α (figure), the distance R _E between the antenna and the radar absorbing device is determined by the formula

,

,

, при этом высота радиопоглощающего устройства является минимальной из возможных.where H _A is the height of the phase center of the antenna above the horizontal plane, R is the distance between the phase center of the antenna and the vertical axis passing through the center of the measuring volume, D _P is the size of the measuring volume in depth, α is the angle of inclination of the profile of the measuring path to the horizontal, Н ₀ - the height of the lower boundary of the measuring volume relative to the horizontal plane, Н _Р - the size of the measuring volume in height, while the width of the radar absorbing device is chosen not less than the length of the small axis of the ellipse of the first Fresnel zone of the antenna, and the height about limit by the formula

while the height of the radar absorbing device is the smallest possible.

The work of the proposed radar system for measuring the diagram of the effective scattering area of objects is no different from the work of the prototype. The difference lies in the preliminary preparation of the complex for measurements [A.B. Shmelev. The influence of the underlying surface on the operation of terrestrial antenna systems. Radio engineering, No. 10, 1998, pp. 105-110]. The profile of the measuring path of the radar measuring complex is inclined, while the rotary support device with the measured object is placed at the top of the measuring path, and the antenna is at the bottom, the installation location of the radar absorbing device, its height and width are determined.

The radar absorbing device can be made in the form of a broadband radar absorbing material of the “Vors” or “Ternovnik” type, which is placed on the frame of a given size from plywood, wire or a nylon cable.

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 were found in public sources of information, namely, the profile of the measuring path is inclined, while the rotary support device with the measured object is located at the upper point of the measuring path, and the antenna is at the bottom, in addition, the introduction of a radar absorbing device, being strengthened at the measuring path at a distance from the antenna, which is determined by the formula

,

,

the width of the radar absorbing device is chosen not less than the length of the small axis of the ellipse of the first Fresnel zone of the antenna, and the height is determined by the formula

.

.

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 measurements of the EPR diagram of objects by eliminating the influence of a specularly reflected irradiating electromagnetic field from the underlying surface on the formation of the resulting amplitude-phase distribution of the electromagnetic field in the measuring volume and background reflection from elements located behind the object in the pulsed volume, therefore, the claimed image tenie corresponds to the condition of "inventive step".

The invention "Radar measuring complex" is industrially applicable, since the set of characteristics characterizing it provides the possibility of its implementation, operability and reproducibility for measuring the EPR of objects at radio measuring ranges, since known materials and equipment can be used to implement the claimed device.

Claims (1)

A radar measuring complex comprising a receiver, calculator, pulse transmitter, antenna switch and antenna connected in series, while the second output of the antenna switch is connected to the receiver input, as well as a slewing ring with a measured object located in the measuring volume, and a control panel, which the first, second and third outputs are connected to the second input of the transmitter, the input of the rotary device and the second input of the computer, respectively, in addition, the computer is the third the input is connected to the output of the rotary device, characterized in that the profile of the measuring path is made inclined, while the rotary support device with the measured object are located at the upper point of the measuring path, and the antenna is at the bottom, in addition, a radar absorbing device installed on it measuring path at a distance from the antenna, which is determined by the formula

where H _A is the height of the phase center of the antenna above the horizontal plane, R is the distance between the phase center of the antenna and the vertical axis passing through the center of the measuring volume, D _P is the size of the measuring volume in depth, α is the angle of inclination of the profile of the measuring path to the horizontal, Н ₀ is the height of the lower boundary of the measuring volume relative to the horizontal plane, H _P is the size of the measuring volume in height, while the width of the radar absorbing device is chosen not less than the length of the small axis of the ellipse of the first Fresnel zone of the antenna, and the height divided by the formula

.

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