RU2560935C1 - Method of measuring radar cross-section of parts of large objects - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: method of measuring the radar cross-section of large objects includes mounting an object on a rotary support; measuring the background; calibrating the fixed object when the object is completely covered with radar absorbent material; irradiating and determining the power of reflected signals when the object rotates around a vertical axis, wherein the object is broken into parts; measuring the power of the reflected signals from the parts while consecutively removing the radar absorbent material from said parts and determining the radar cross-section of the parts; obtaining an integral radar cross-section by comparing measurements taken in a standard state and with a masked part, wherein the relative contribution of each part of the object in the in integral radar cross-section in the given angular sector is determined in accordance with the expression:

where

is the average radar cross-section of the object in a standard state and with a masked part, respectively. The radar absorbent material used is a material with an electromagnetic radiation reflection coefficient on a metal surface of not more than -20 dB in the operating frequency range and electromagnetic radiation polarisation.

EFFECT: determining the radar cross-section of parts of an object for different aspects.

2 cl

Description

The invention relates to radar and can be used to experimentally evaluate the contribution of sections of a large-sized object, for example an aircraft turbojet engine, to the integral value of the effective scattering surface (EPR) of the engine. Such an assessment is important for specialists developing methods and means of reducing the EPR of the engine, since it allows to identify the most critical nodes that make the main contribution to the EPR of the engine.

The parameters of the scattered radar target of an electromagnetic wave are amplitude and phase. The amplitude of the scattered radar target of the electromagnetic wave determines the ESR of the target. EPR - a value that characterizes the radar signature of the target. The range and probability of target detection by radar depend on the magnitude of the EPR. In military affairs, they seek to reduce the EPR of objects so that they are less noticeable to enemy radars.

The closest in technical essence and the achieved technical result is a known method of measuring the effective scattering surface of large-sized objects, including installing the object on a rotary support device, measuring the background, calibrating a stationary object, irradiating and determining the power of the reflected signals when the object rotates around a vertical axis. The stationary object is standardized at the moment when its projection onto the rear wall is minimal, for which the object is closed from the irradiation side with a radio-absorbing screen and the residual reflections are compensated. Then establish a reference reflector with a known EPR in front of the radar absorbing material and determine the power of the signal reflected from a reference reflector with a known EPR. The power of the reflected signal during rotation of the object around the vertical axis calculates the ESR of the object (RU 2488135 C1, G01S 13/10, 07/20/2013).

However, the known method does not allow to evaluate the contribution of the object’s sections to the integral value of its EPR, since it considers the entire object at once without analyzing its components.

The objective of the invention is to develop a method for determining the EPR of the site, approximation to the actual conditions of the layout.

The expected technical result is to determine the EPR of the site sections for various viewing angles.

The expected technical result is achieved by the fact that the known method of measuring the effective scattering surface of large objects, including installing the object on a rotary support device, measuring the background, standardizing a stationary object when it is completely covered by radar absorbing material, irradiating and determining the power of the reflected signals when the object rotates around a vertical axis , characterized in that the object is divided into sections, measure the power of the reflected signals from the sections with sequential removal a radio absorbing material and are determined ESR portions are then obtained by comparing the integral of EPR measurements performed in the normal state and the masked portion, the relative contribution of each portion of the object in the integrated ESR in a predetermined angular sector determined according to the expression:

- средние значения ЭПР объекта в штатном состоянии и с замаскированным участком соответственно. В качестве радиопоглощающего материала используют материал с коэффициентом отражения электромагнитного излучения на металлической поверхности не более -20 дБ в рабочем диапазоне частот и поляризации электромагнитного излучения.Where

- average values of the EPR of the object in the normal state and with the masked area, respectively. As a radar absorbing material, a material with a reflection coefficient of electromagnetic radiation on a metal surface of not more than -20 dB in the operating frequency range and polarization of electromagnetic radiation is used.

We describe the essence of the invention.

The object is placed on a rotary support device, which allows you to determine the EPR of the object sections for various viewing angles. The angular sector of measurements can be both a full revolution (360 °) in the horizontal plane, and its individual sectors for given fixed elevation angles of the object.

During the preparation and conduct of the measurements, the influence and auxiliary equipment, weather conditions and multipath propagation of radio waves on the measuring path of the radar measuring complex are evaluated and eliminated (reduced) on the results of measurements of the average ESR values of the object in the given angular sectors. To this end, measures are being taken to reduce the level of reflections from the slewing ring, the underlying surface of the measuring path and to control the metrological characteristics of the complex during experimental studies of the radar visibility of the object. To do this, during the measurements, a radar absorbing material with a reflection coefficient of electromagnetic radiation on a metal surface of not more than -20 dB in the operating frequency range is used. To ensure sufficient measurement quality of the amplitude diagrams of the backscattering of sections of the object, it is required that the electromagnetic background of the object when measuring is small enough. Therefore, the reflection coefficient of electromagnetic radiation of a radar absorbing material on a metal surface should be a value characteristic of modern samples of radar absorbing materials — not more than -20 dB in the operating frequency range of electromagnetic radiation. With a higher reflection coefficient of the radar absorbing material, the object can significantly reflect electromagnetic radiation during standardization and thereby degrade the quality of the measurement of amplitude backscatter diagrams of sections of the object.

Background measurement is carried out to estimate the minimum value of the EPR. To do this, measure the power of the reflected signals from a rotating object, completely covered by radar absorbing material.

The standardization is carried out to calibrate the receiving paths of the transmission system. The standardization of a stationary object is performed when it is completely covered by radar absorbing material. To do this, the object using the rotary support device is set to a position with a minimum value of the echo signal in the direction of the radio complex. In front of the object, a reference reflector is placed on a small rotary platform, which is rotated and the power of the reflected signals is measured. Certified metal cylinders and trihedral corner reflectors with EPR exceeding the EPR of the residual background of the complex by 20 dB or more are used as a reference reflector. The measurements in the proposed method are carried out by the method of relative measurements of the integral EPR, in which the measurement and subsequent comparison of the power of the signal reflected from the object with the power of the signal reflected from the reference reflector is performed.

To assess the relative contribution to the EPR of an object of its sections, as well as the effectiveness of using special means of reducing visibility on it, a comparison method is used, which involves measuring the EPR for two states of the object: standard and using materials that change the reflective properties of the object (its sections) by screening or masking with radar absorbing material. To do this, the areas of interest of the object are sequentially released from the radar absorbing material, each time measuring the amplitude diagram of the backscattering of the object. Measurements are carried out when the object is rotated on a slewing ring. In the case of researching an aircraft turbojet engine, EPR measurements of such sections as the engine entrance (external guide apparatus), nozzle, both the external and internal surfaces (supersonic flaps), front-end device, and coke are measured.

The experimental data is processed and the EPR angular diagrams and static EPR characteristics are obtained in the given sectors of the object observation. The assessment of the relative contribution of the engine section to its integral EPR in a given angular sector is determined in accordance with the expression:

- средние значения ЭПР объекта в штатном состоянии и с замаскированным участком соответственно.Where

- average values of the EPR of the object in the normal state and with the masked area, respectively.

The proposed method is as follows.

Aircraft turbojet engine 117C is mounted on a rotary support device so that its center of mass coincides with the axis of rotation of the platform. They carry out activities aimed at reducing the level of reflections from the positioning device of the object. To do this, the engine, the slewing ring and the covering surface are completely covered with the RAS-68 radar absorbing material with a reflection coefficient of electromagnetic radiation on the metal surface of not more than -25 dB in the operating frequency range of the radar station. The test engine is set to its initial position relative to the radio measuring complex by turning the platform of the slewing ring at the desired angle. The rotary support device is rotated and the echo signals are received and recorded for the vertical and horizontal polarization of the probe signal. Get the minimum background value of the EPR. Carry out the calibration of the receiving paths of the transmission system, for which a metal cylinder is placed on the low-reflecting support with a small rotary platform in the working volume of the radar measuring complex and oriented to the PPS antenna. To reduce the influence of the test object on the calibration results, it is set to a position with a minimum value of the echo signal in the direction of the radio complex. Turn on the rotation of the small turntable and receive and register echo signals from the reference reflector for the vertical and horizontal polarization of the probe signal. To assess the contribution of the engine sections to the EPR, the engine entrance, nozzle exit, and the outer surface of the nozzle are sequentially released from the radar absorbing material. After the disclosure of each of the listed sections, the rotation of the slewing-rotary device is turned on and the ESR diagrams of the object are measured by sensing, receiving and recording the amplitude of the echo signals synchronously with the current value of the platform rotation angle. At the end of each series of measurements, the platform of the slewing ring is stopped. The experimental data are processed and the relative contribution of each studied section of the engine to its integral ESR in a given angular sector is evaluated.

The proposed method allows to determine the contribution of each section of the measurement object to the EPR of the object and reduce labor costs for the development of measures to protect specific sections. The proposed method also allows measurements with an integral EPR measurement error not exceeding 1 dB (for an object with an EPR ≥1 m ² with a signal-to-background ratio equal to or more than 20 dB), with a probability of 0.95.

Claims (2)

1. The method of measuring the effective scattering surface of large-sized objects, including installing the object on a rotary support device, measuring the background, standardizing a stationary object when it is completely covered by radar absorbing material, irradiating and determining the power of the reflected signals when the object rotates around a vertical axis, characterized in that the object divided into sections, measure the power of the reflected signals from the sections with sequential removal of radar absorbing material from them and determine the EPR section c, then an integral ESR is obtained by comparing measurements taken in the normal state and with the masked area, and the relative contribution of each site of the object to the integral ESR in a given angular sector is determined in accordance with the expression:

Where

- average values of the EPR of the object in the normal state and with the masked area, respectively. 2. The method according to p. 1, characterized in that as a radar absorbing material using a material with a reflection coefficient of electromagnetic radiation on a metal surface of not more than -20 dB in the operating frequency range and polarization of electromagnetic radiation.