RU2377584C1 - Device for measuring coefficient of reflection of electromagnetic waves - Google Patents

Abstract

FIELD: physics; radio.

SUBSTANCE: invention relates to radar, specifically to radar measurements, and can be used for measuring coefficient of reflection (CR) of radiotransparent cowlings (RTC) and flat samples of radar absorbent materials and coatings (RAMC). The device has an antenna system in an anechoic chamber, the analysed object on a stand, a receiving-transmitting device and a unit for calculating coefficient of reflection of electromagnetic waves. The antenna system is made in form of an array of N (N>2) receiving-transmitting elements lying in one plane, spaced by half the wavelength of the electromagnetic waves, and there is a switch for the receiving-transmitting elements of the antenna system and a control unit for the receiving-transmitting device.

EFFECT: more accurate measurement of coefficient of reflection of electromagnetic waves by increasing the dynamic range of measurement and possibility of measuring coefficient of reflection with normal incidence of electromagnetic waves on the analysed object.

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Description

The invention relates to radar, in particular to radar measurements, and can be used to measure the reflection coefficient (KO) of radiolucent antenna fairings (RPO) and flat samples of radar absorbing materials and coatings (RPMP).

One of the main characteristics of RPO and RPMP to be measured is their QoS.

Known devices for measuring the electromagnetic field of electromagnetic waves (EMW) (see Russia, author certificate. No. 647619, IPC G01S 13/00, G01R 29/00, 1979, Japan Z. No. 5-10630, IPC G01S 13/00 , G01R 29/00, 1993 US Pat. No. 4,943,363, IPC G01S 13/00, G01R 29/00, 1990), comprising an antenna system, an object under investigation on a stand and serially connected transceiver and coefficient estimation unit reflection of an electromagnetic wave.

A disadvantage of the known devices is that in these devices as the antenna system they use one transceiver antenna in conjunction with microwave elements decoupling the probing and received signals. Signal isolation narrows the dynamic range of the device.

The closest in technical essence device is a device for measuring dielectric constant (see. "Surface waves and microwave devices for monitoring the electrophysical parameters of magnetodielectric coatings on metal", edited by N.P. Fedorov. M.: Mashinostroenie-1, 2004 city, p.20), containing the antenna system, the test object on the stand and connected in series to the transceiver and the unit for evaluating the reflection coefficient of the electromagnetic wave.

The principle of operation of the device closest in technical essence is as follows. An electromagnetic wave from a transceiver device enters the transmitting antenna and is emitted in the direction of the object under study. The wave reflected from the object enters through the receiving antenna into the receiving and transmitting device, where it is amplified and converted into the necessary shape, and fed to the indicator.

The disadvantage of the closest technical solution is the low accuracy of measuring KO EMV.

The technical result of the invention is to increase the accuracy of measuring KO EMV by increasing the dynamic range of measurement and providing the ability to measure KO with a normal incidence of EMV on the studied object.

The specified technical result is achieved by the fact that in the known device for measuring the electromagnetic field EMF, containing the antenna system in the anechoic chamber, the test object on the stand and connected in series to the transmitting and receiving device and the unit for evaluating the reflection coefficient of the electromagnetic wave, characterized in that the antenna system is made in the form arrays of N (N> 2) transceiver elements located on the same plane, with a step equal to half the length of the electromagnetic radiation wave, a transceiver switch is introduced elements of the antenna system and the control unit of the transceiver, to the input of which is connected the unit for evaluating the reflection coefficient of the electromagnetic wave, and to the first and second outputs, respectively - the unit for evaluating the reflection coefficient of the electromagnetic wave and the switch of the transceiver elements of the antenna system, to the inputs of which the receiver is connected - transmitting device and one of the transceiving elements of the antenna system.

The proposed design of the device allows you to evaluate the EMF EMF with a normal EMF drop without reducing the dynamic range due to the need for isolation of the receiving and probing signals with a combined transmitting and receiving antenna system.

The analysis of the prior art allows us to establish that analogues that characterize a set of features that are identical to all the features of the claimed technical solution contained in the claims proposed by the applicant are absent, which indicates compliance of the claimed invention with the “novelty” protection condition.

Search results for known solutions in this and related fields of technology in order to identify features that match the distinctive features of the claimed device 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 claimed technical result, therefore, the claimed invention meets the condition of patentability "inventive step".

The claimed technical solution "Device for measuring the reflection coefficient of an electromagnetic wave" is industrially applicable, since the combination of characteristics characterizing it provides the possibility of its implementation, performance and reproducibility, and standard materials and equipment can be used for its implementation.

The invention consists in the following. At the first stage, EMW E _i (r) is sequentially emitted by each element of the antenna system, where r is the coordinate of the ith element of the antenna system. At each irradiation of the object’s electromagnetic field, the scattered electromagnetic field is recorded sequentially by all elements of the antenna system. At the second stage, weight processing of the array of registered scattered electromagnetic waves E _pn (r), (n = 1, ..., N) is carried out. After processing the measurement results, an estimate of the EMF coefficient is obtained with a normal EMF drop.

Figure 1 presents a structural diagram of the inventive device for measuring KO EMV. Figure 2 presents the algorithm of the evaluation unit TO EMW.

SUBSTANCE: device for measuring electromagnetic radiation emitter contains transmitting and transmitting device 1, antenna system 2, transmitting and transmitting elements of antenna system 2 ₁ ÷ 2 _N , block for evaluating reflection coefficient of electromagnetic wave 3, switch for transmitting and transmitting elements of antenna system 4, control unit for receiving and receiving switch transmitting elements of the antenna system 5, sample 6, stand 7, anechoic chamber 8. The output of the transceiver 1 is connected to the transceiver elements 2 ₁ ÷ 2 _{N of the} antenna system 2 through the switch of the transceiver elements an antenna system 4, the antenna system 2 through the switch of the transceiver elements of the antenna system 4 is connected to the input of the transceiver 1, the second output of which is connected to the input of the evaluation unit of the EMF 3, the output of the evaluation module of the EMF 3 is connected to the control unit of the transmitter-receiver switch transmitting elements of the antenna system 5, the output of which is connected to the switch of the transmitting and receiving elements of the antenna system 4. The measurement object 6 is installed on the stand 7, and the entire device is in an anechoic chamber 8.

A device for measuring KO EMV objects can be performed in the range from 0.8 to 15 cm using the following functional elements.

As the transceiver 1, a vector network analyzer can be used as a sensitive broadband device.

The switch of the transceiver elements of the antenna system 4, electrically controlled by the control unit, the switch of the transceiver elements of the antenna system 5.

, где λ - длина волны, на которой необходимо оценить КО ЭМВ. Излучающие элементы могут быть выполнены в виде полуволновых вибраторов или рупорных антенн.Antenna system 2 consists of N (N> 2) transceiver elements 2 ₁ ÷ 2 _N , mounted on the same plane and fixed to the base of a composite material. The placement of the transceiver elements 2 ₁ ÷ 2 _{N of the} antenna system 2 is selected in steps

, where λ is the wavelength at which it is necessary to estimate the electromagnetic field TO. The radiating elements can be made in the form of half-wave vibrators or horn antennas.

The control units for the switch of the transceiver elements 2 ₁ ÷ 2 _{N of the} antenna system 5 and the evaluation unit of the TOE EMV 3 can be made in the form of a personal computer of the IBM type, combining control and computing functions.

The remaining blocks and devices that are part of the device for measuring KO EMW can be performed by known methods. A device for measuring KO EMV installed in an anechoic chamber 8, operates as follows.

The measurement object 6 is placed on a stand 7. The transceiver 1 generates high-frequency oscillations that, through the switch of the transceiver elements of the antenna system 4, controlled by the control unit of the switch of the transceiver elements of the antenna system 5, go to the first transceiver element 2 _{1 of the} antenna system 2 and measurement object 6 is irradiated with electromagnetic radiation, reflected electromagnetic waves from measurement object 6 are sequentially received by all transceiver elements 2 ₁ ÷ 2 _{N of} antenna system 2. The data array is recorded It is entered in the block of the evaluation of the EMV 3 computer (computer). Then, the switch of the transceiver elements of the antenna system 4 using the control unit switch of the transceiver elements of the antenna system 5 connects the next transceiver element 2 ₁ ÷ 2 _{N of the} antenna system 2. The cycle is repeated until the test object 6 is irradiated with all the transceiver transmitting elements 2 ₁ ÷ 2 _N antenna system 2.

Then, the test object 6 is removed from the stand 7 and the entire measurement cycle is repeated. Records the results of measurements of scattered electromagnetic waves without the investigated object 6.

When processing the measurement results, the measurement results of the scattered EMW without the test object 6 are subtracted from the measurement results of the scattered EMW with the test object.

Processing of the measurement results in block 3 is performed according to the following algorithm (figure 2).

At the first stage of processing, the complex amplitude of the EMW scattered by the investigated object is calculated in relation to its normal fall using the formula

where E is the complex amplitude of the EME scattered by the studied object as applied to the normal incidence and direction of reception,

a _n - weighting coefficients, determined by minimizing the deviation of the total EME of the transmitting and receiving elements 2 ₁ ÷ 2 _{N of the} antenna system 2 from the normally incident on the investigated object 6 EMV,

A _n is a vector whose elements contain phase differences and level ratios recorded by the transceiver elements 2 ₁ ÷ 2 _{N of the} antenna system 2 when the object is irradiated with the n-th transceiver element 2 _{n of the} antenna system 2. At the second stage, the electromagnetic field emissivity is calculated by the formula

E _met - the complex amplitude of the scattered metal plate EMW in relation to the normal incidence and direction of reception.

Claims (1)

A device for measuring the reflection coefficient of an electromagnetic wave, comprising an antenna system in the anechoic chamber, a test object on a stand, and a transceiver device and an electromagnetic wave reflection coefficient evaluation unit connected in series, characterized in that the antenna system is made in the form of an array of N (N> 2 ) transceiver elements located on the same plane, with a step equal to half the length of the electromagnetic wave irradiation of the sample, and the switch transceiver elements antenna system and the control unit of the transceiver device, the input of which is connected to the unit for evaluating the reflection coefficient of the electromagnetic wave, and to the first and second outputs, respectively, is the unit for evaluating the reflection coefficient of the electromagnetic wave and the switch of the transceiver elements of the antenna system, to the inputs of which the transceiver device and one of the transceiver elements of the antenna system.

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