RU2326400C1 - Method of measurement of efficient scattering area of large dimension objects in polygon conditions - Google Patents

Abstract

FIELD: radio location.

SUBSTANCE: method consists in radiation of measurement object, measurement of circular graph of measurement object, which is installed on rotating platform, by power, its orientation with minimum of efficient scattering area (ESA) graph to RLS, placement on additional rotation device in pulse volume of RLS between the rotating platform and RLS of reference reflector with available ESA, its rotation, determination of maximum of signal reflected from the reference reflector, its displacement in relation to the measurement object at the distance, which is more or equal to the length of wave of radiating signal of RLS, registration of level of vector sum of signals, which are reflected from the object and movable reference reflector, selection of maximum and minimum values of power levels of reflected signals, with the help of which the ESA is determined in the point of measurement object interaction with reference reflector by certain formula and then calculation of ESA of measurement object.

EFFECT: increases accuracy of ESA measurement at the account of ESA graph calibration by reference reflector.

1 dwg

Description

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

The measurement of the effective dispersion area (EPR) of large-sized objects (airplanes, tanks, etc.) at open ranges is characterized by a large amount of preparatory work, one of which is the installation of the measuring object on a rotary device, and its location in the measuring volume. For example, installing an aircraft on a rotary device in a measuring volume takes from six to ten hours. In this case, during measurements it is necessary to remove the measurement object from the measuring volume and replace it with a reference reflector for calibration. According to the measurement requirements, the time between the removal of an object and its replacement with a reference reflector should be reduced to a minimum.

A known method of measuring the EPR of objects (TIIER, 1965, t.53, No. 8, p.1051), in which at any time either the measurement object or the reference reflector is irradiated. For this, the rotation device is made so that it can be installed on it the measurement object and the standard at the same time. In this case, the measurement object and the reference reflector alternately fall into the irradiation zone.

The disadvantage of this method is the inability to measure the EPR of large-sized objects (aircraft, tanks, etc.) due to the practical impracticability of the corresponding rotation device for real large-sized objects.

There is also a method of measuring the EPR of objects (RF patent No. 2217774, IPC 7 G01S 13/00, G01R 29/02, 2003), which includes the radiation of the probe signal, measuring the power P _{m of the} received signal reflected from the object and the distance R to the object, at least two additional radiation of the signal and measurement of the received signal powers P ₁ , P ₂ in the vicinity of the direction to the object are performed, the signal power P _n is calculated, which corresponds to the maximum position of the antenna radiation pattern (BOTTOM) with independent signal fluctuations s reflected from the object, according to the formula

Where

P _m is the power of the received signal during measurement;

P ₁ , P ₂ - power of the received signals with two additional measurements;

σ _W ² - power of own noise;

Δε, Δβ - beam pitch in elevation (ε) and azimuth (β), respectively, normalized to the corresponding beam width at half power level;

α = 5.56 - coefficient determining the steepness of the exponent describing the shape of the main beam of the bottom,

and calculating the EPR of an object using the formula

where P _ss is the power of the probing signal;

R is the distance to the object;

G is the antenna gain;

λ is the wavelength;

P _n is the power of the received reflected signal.

In this case, the radiation of the probe signal is produced with a sufficiently small delay, eliminating the distortion of the measurement results when moving the object.

The disadvantage of this method is the lack of calibration on a reference reflector and, therefore, low accuracy of the EPR measurement. This is due to the fact that measurements are carried out in real conditions of movement of the measurement object, where it is difficult to achieve repeatability of the measurement results.

A new technical result is to increase the accuracy of measuring the EPR of large objects of the proposed method.

The technical result is achieved due to the fact that in the known method for measuring the effective dispersion area of large objects in polygon conditions, including irradiating the object, measuring the power of the reflected signal using a radar station and recording the reflected signals, they also measure the pie chart of the measured object by power P _n (φ) mounted on a rotating platform, orient the object with a minimum of the EPR diagram on the radar, then in the pulsed volume of the radar between the rotating platform and the radar and an additional rotation device places a reference reflector with a known EPR (σ _et ), rotates it, determines the maximum of the signal reflected from the reference reflector, moves it relative to the measurement object by a distance greater than or equal to the wavelength of the irradiating radar signal, records the power level of the vector sum of signals, reflected from the object and the movable reference reflector, select the maximum P _max and minimum P _{min the} values of the power levels of the reflected signals, with which help determine the EPR at the point of mutual the action of the measurement object with a reference reflector according to the formula

and then calculate the EPR of the measurement object for any angle φ, using the EPR at the point of interaction σ _vz and the interaction power P _vz according to the formula

The proposed method for measuring the EPR of objects allows calibration without removing the object from the measurement zone. For this, the reference reflector is mounted on an additional rotation device, which, in addition to rotation, has the ability to move in a straight line coinciding with the line of sight. Placing the reference reflector in the same pulsed volume with the measured object ensures wave interaction of the echo signals reflected from them and, therefore, interference modulation of the power of the total echo signal. In this case, the ESR of the reference reflector σ _et should be comparable with the ESR of the measured object. In this case, the EPR at the point of interaction σ _vt approaches the EPR of the reference reflector σ _et . In the remaining cases, _σtz will be less than _σt , which is undesirable due to the increasing signal-to-noise ratio in determining _σtr and can lead to an increase in the measurement error. The point on the measurement object and the power P _b , in which σ _bc is determined, is used as a reference point, with the help of which the ESR of the object σ _n (φ) is determined for all viewing angles.

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

Search results for known solutions in this and related fields of technology in order to identify features that match the distinguishing features of the proposed method showed that no solutions having features matching its distinctive features were found in publicly available information sources. The prior art also does not confirm the popularity of the influence of the distinctive features of the claimed invention on the specified technical result, therefore, the claimed invention meets the condition of "inventive step".

The proposed technical solution "Method for measuring the EPR of large-sized objects in landfill conditions" is industrially applicable, since the combination of characteristics characterizing it provides the possibility of its implementation, operability and reproducibility at radio measuring ranges.

The drawing shows a device that implements the inventive method of measuring the EPR of large objects in polygon conditions.

The device consists of a radar 1, a fragment of the EPR diagram 2, a reference reflector 3, a rotating platform 4, an object of measurement 5, an additional rotation device 6, a line of sight 7, and the radar 1 is located at some distance from the rotating platform 4 (about 1 km), which installed at ground level and on which the measurement object 5 is placed. Near the rotating platform 4, an additional rotation device 6 is installed on which the reference reflector 3 is placed.

A device that implements a method for measuring the EPR of large-sized objects in polygon conditions, works as follows. The measurement object 5 is installed on the rotating platform 4. The radar 1 emits sounding signals in the direction of the measurement object 5, which is rotated by the rotating platform 4, the power of the reflected signals from the measurement object 5 (P _n ) is measured during the entire rotation of the rotating platform 360 degrees and as a result, an EPR pie chart of the object in terms of power P _{n is} obtained (a fragment of this diagram is shown in the drawing). After that, they continue to rotate the measurement object - 5 until they orient it by the minimum of the EPR diagrams on the radar 1, then in the pulse volume of the radar 1 between the rotating platform 4 and the radar 1 on the additional rotation device 6 place a reference reflector 3 with a known EPR (σ _fl), rotate it, determine the maximum reflected from the reference reflector 3 signal, it is moved relative to the measurement object 5 at a distance greater than or equal to the wavelength of the illuminating radar signal 1, record power level vector sum signals, trazhennyh the measuring object 5 and the movable reference reflector 3 is selected maximum P _max P _min and minimum values of power levels of the reflected signals, whereby the ESR is determined at the point of interaction of the measurement object 5 with the reference reflector 3 according to the formula

This formula is obtained from the solution of the system of equations (5) and (6) for the interaction of two reflectors

and then calculate the EPR of the measurement object 5 for any angle φ, using the EPR at the point of interaction σ _vz and the interaction power P _vz according to the formula

Using this method of measuring the EPR of large-sized objects in polygon conditions allows to increase the measurement accuracy by at least 4-5 dB due to the calibration of the EPR diagram by a reference reflector. In this case, the object is in a stationary position and high repeatability of the measurement results is achieved. In addition, the measurement efficiency is significantly increased.

Claims (1)

A method for measuring the effective scattering area (EPR) of large-sized objects in polygon conditions, including irradiating the measurement object, measuring the power of the signal reflected from the measurement object using a radar station and recording the reflected signals, characterized in that they additionally measure the circular diagram of the measurement object by power P _n (φ), mounted on a rotating platform, it is oriented for minimum radar EPR diagram, then a radar pulse volume between the rotating platform and a radar for additional Yelnia device rotation positioned reference reflector with a known ESR (σ _fl) is rotated it is determined maximum reflected from the reference signal reflector, for moving it with respect to the measurement object at a distance greater than or equal to the wavelength of the illuminating radar signal, record the power level of the vector sum of signals reflected from object and a moving reference reflector, select the maximum P _max and minimum P _{min the} values of the power levels of the reflected signals, with the help of which they determine the EPR at the point of interaction measurement object with a reference reflector according to the formula

and then calculate the EPR of the measurement object for any angle φ, using the EPR at the point of interaction σ _vz and the interaction power P _vz according to the formula

.