RU2649037C1 - Compact broadband four-component receiving antenna device - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: device relates to the radio-receiving equipment and can be used in radio direction finding, radio navigation and radio monitoring. Device, in addition to the known solution, comprises a fourth balanced transformer, a fourth connector, fourth shielded communication lines, receiving frame magnetic antenna, consisting of four flat identical sections of a multi-turn shielded coil with an annular slot in the shield of each flat section. Flat identical sections of a multi-turn shielded coil are located axially symmetrically in one plane around the central axis of the device. Each flat section of a multi-turn shielded coil is located above the corresponding flat segment of the upper metal electrode of the receiving electrical antenna. Turns of each section and all flat sections of the multi-turn shielded coil are successively electrically connected to each other, forming the winding of the receiving frame magnetic antenna. Receiving frame magnetic antenna is separated from the upper metal electrode of the receiving electrical antenna by a flat dielectric spacer with a central hole. Wires of the fourth shielded lines are connected to the winding of the receiving frame magnetic antenna, wires electrically connect this winding to the differential input of the fourth balanced transformer, output of which is electrically connected to the fourth connector. Fourth shielded communication lines are laid along the surface of the electric shield of the lower receiving magnetic antenna on the rod ferrite core, the end elements of the antenna drop and metal base are symmetrical with respect to the central section of the core of the lower receiving magnetic antenna, and the shielding casings of the fourth shielded communication lines are electrically connected to the electric shield of the multi-turn shielded coil of the receiving frame magnetic antenna, electric shield of the lower receiving magnetic antenna on the rod ferrite core, end elements of the antenna drop and metal base.

EFFECT: technical result is the possibility of bearing along the angle together with bearing along the azimuth angle to determine the location of elevated sources of electromagnetic radiation.

1 cl, 3 dwg

Description

The device relates to radio technology and can be used in the field of direction finding, radio navigation and radio monitoring.

The identification and analysis of radio emissions to identify sources of signals and interference, measuring the parameters of signals and interference, determining the position of sources on the ground are the most important tasks of modern radio engineering.

In solving these problems, particularly high demands on sensitivity, broadband, bearing error and noise immunity are imposed on antenna devices - primary converters of the electromagnetic field.

Known conjugate direction-finding antenna in the range of 0.5-30 MHz [1], containing two mutually orthogonal receiving magnetic antennas on rod ferrite cores, which have a profile with angles that reduce the reflection of radar radiation, and located crosswise, with windings on each of them located symmetrically with respect to the central sections of the cores, the differential outputs of which are connected to the differential inputs of the balancing transformers, the outputs of which are connected to the connectors, all These elements are protected by a casing and placed on a metal base, and from the output of the connectors with the help of cables the received radio signals are transmitted to the input of the receiving electronic device.

The symmetry of the elements of the device allows you to quite effectively suppress the in-phase component of the interfering signal from the electrical component of the electromagnetic field.

The disadvantage of this analogue is the weak polarization isolation between mutually orthogonal receiving antennas and, as a result, a significant error in determining the bearing. The achievable polarization isolation in antenna devices with mutually orthogonal cross-shaped arrangement of receiving magnetic antennas, combining the broadband and mutual symmetry of their elements, does not exceed 40 dB at frequencies of about 100 kHz, 30 dB at frequencies of about 1 MHz and 21 dB at frequencies about 10 MHz and higher. If the bearing accuracy requirement is 1 ÷ 2, it is necessary to have a decoupling of at least 40 dB.

Also known is a broadband two-component receiving antenna device [2], containing a metal base, on which two mutually orthogonal receiving antennas are placed on rod ferrite cores arranged crosswise, with windings on each of the core sections symmetrically relative to the central sections of the cores, symmetrical transformers and connectors , the differential outputs of the windings are connected to the differential inputs of the transformers, and the outputs of the balancing transformer ov - with connectors, from the outputs of which the received radio signals are transmitted through cables to the input of the receiving electronic device, electric screens of the receiving antennas with longitudinal slots, shielded communication lines, end elements of the antenna reduction, the receiving magnetic antennas are vertically offset from each other, located above the metal the base, the plane of which is parallel to the longitudinal axes of the magnetic antennas, the windings of each of the receiving magnetic antennas are placed in their own electric screen with a longitudinal the gap at the intersection of the antennas, the screens of the upper and lower receiving magnetic antennas are electrically connected to each other, with the longitudinal slit of the screen of the upper receiving magnetic antenna facing up, the longitudinal slit of the screen of the lower receiving magnetic antenna facing down, symmetrically connected to the end edges of the screen of the lower receiving magnetic antenna electrically conductive structurally identical end elements of the antenna reduction, closing electrical screens on a metal base, and shielded communication lines between at the differential outputs of the receiving antennas and the differential inputs of the balancing transformers are laid along the screen surfaces of the lower receiving magnetic antenna, the end reduction elements and the metal base symmetrically with respect to the central section of the core of the lower receiving magnetic antenna, and the shielding of the communication lines are electrically connected to the screen of the lower receiving magnetic antenna, end drop elements and a metal base.

The use of constructive and technical solutions proposed in this device allows one to reduce the influence of interference on a useful signal, as well as to improve polarization isolation to a value of at least 40 dB in the frequency range up to 10 MHz.

The disadvantage of this device is the ambiguity of the determination of the bearing (true bearing and bearing, which differs from the true 180 °), due to the lack of the possibility of binding polarizations of mutually orthogonal electrical and magnetic components of the received electromagnetic signals.

The closest in technical essence (prototype) is a compact broadband three-component receiving antenna device [3], containing a metal base, on which there are two mutually orthogonal receiving magnetic antennas on rod ferrite cores, located crosswise, with windings on each of the cores located symmetrically relative to the central sections of the cores, the first and second balancing transformers, the first and second connectors, differential outputs of the coil ok electrically connected to the differential inputs of the respective balancing transformers, and the outputs of the first and second balancing transformers are electrically connected to the corresponding connectors, the electric screens of the receiving magnetic antennas with longitudinal slots, the first and second shielded communication lines, the end elements of the antenna reduction, the receiving magnetic antennas are offset relative to each other each other vertically, located above a metal base, the plane of which is parallel to the longitudinal axes of the receiving magnetic antennas, the windings of each of the receiving magnetic antennas are placed in their own electric screen with a longitudinal slit, at the intersection of the antennas, the screens of the upper and lower receiving magnetic antennas are electrically connected to each other, while the longitudinal slit of the screen of the upper receiving magnetic antenna is facing up, the longitudinal slit of the screen the lower receiving magnetic antenna is facing downward, to the end edges of the screen of the lower receiving magnetic antenna are electrically conductively symmetrically connected electrically conductive identical the end elements of the antenna reduction, closing the electrical screens to the metal base, and the first and second shielded communication lines between the differential outputs of the receiving magnetic antennas and the differential inputs of the balancing transformers are laid along the surfaces of the screen of the lower receiving magnetic antenna, the end elements of the reduction and the metal base are symmetrical with respect to the central section the core of the lower receiving magnetic antenna, and the shielding shells of the first and second shields These communication lines are electrically connected to the screen of the lower receiving magnetic antenna, the end reduction elements and the metal base, the third balancing transformer, the third connector, the third shielded communication lines, the upper and lower metal electrodes, each consisting of four flat segments, the projection of four flat segments onto the metal the base does not go beyond it, four flat segments are axially symmetrically located in one plane around the central axis of the device and are electrically are interconnected at a common point lying on the central axis of the device, the plane of the upper electrode located above the upper receiving magnetic antenna and the plane of the lower electrode located below the lower receiving magnetic antenna, and both electrodes form a receiving electric antenna of the capacitor type, to the common points of each electrode which is connected to the veins of the third shielded lines, electrically connecting the electrodes with the differential input of the third balancing transformer, the output of which is electric eski is connected to the third connector, laid along the surfaces of the screen of the lower receiving magnetic antenna, the end elements of the reduction and the metal base symmetrically with respect to the center section of the core of the lower receiving magnetic antenna, and the shielding shells of the third shielded communication lines of the receiving electric antenna are electrically connected to the screen of the lower receiving magnetic antenna, end reduction elements and a metal base.

The disadvantage of the prototype is the lack of the ability to carry out a bearing by elevation along with a bearing by azimuth angle to determine the location of elevated sources of electromagnetic radiation.

The technical result of the invention is the ability to perform direction-finding bearing along with bearing on azimuth angle to determine the location of elevated sources of electromagnetic radiation.

The technical result is achieved by the fact that a compact broadband four-component receiving antenna device containing a metal base, on which there are two mutually orthogonal receiving magnetic antennas on rod ferrite cores located crosswise, with windings on each of the cores located symmetrically relative to the central sections of the cores, the first and second balancing transformers, first and second connectors, differential leads of the windings electrically connected s with differential inputs of the corresponding balancing transformers, and the outputs of the first and second balancing transformers are electrically connected to the corresponding connectors, the electric screens of the receiving magnetic antennas with longitudinal slots, the first and second shielded communication lines, the end elements of the antenna reduction, the receiving magnetic antennas are offset relative to each other verticals, located above a metal base, the plane of which is parallel to the longitudinal axes of the receiving magnetic antennas, obm The webs of each of the receiving magnetic antennas are placed in their own electric screen with a longitudinal slit, at the intersection of the antennas, the electric screens of the upper and lower receiving magnetic antennas are electrically connected to each other, while the longitudinal slit of the screen of the upper receiving magnetic antenna is facing up, the longitudinal slit of the screen of the lower receiving magnetic the antenna is facing down, to the end edges of the screen of the lower receiving magnetic antenna, electrically conductive structurally identical end faces are symmetrically electrically connected antenna reduction elements closing electrical screens to the metal base, and the first and second shielded communication lines between the differential outputs of the receiving magnetic antennas and differential inputs of the balancing transformers are laid along the surfaces of the screen of the lower receiving magnetic antenna, the end elements of the antenna reduction and the metal base are symmetrical with respect to the central section of the core lower receiving magnetic antenna, and shielding shells of the first and second shields These communication lines are electrically connected to the screen of the lower receiving magnetic antenna, the end elements of the antenna reduction and the metal base, the third balancing transformer, the third connector, the third shielded communication lines, the upper and lower metal electrodes, consisting of four flat segments, the projection of four flat segments onto the metal the base does not go beyond it, four flat segments are axially symmetrically located in one plane around the central axis of the device and are electrically interconnected at a common point lying on the central axis of the device, the plane of the upper electrode located above the upper receiving magnetic antenna, and the plane of the lower electrode located below the lower receiving magnetic antenna, and both electrodes form a receiving electric antenna of the capacitor type, to the common points of each electrode which is connected to the veins of the third shielded communication lines, electrically connecting the electrodes with the differential input of the third balancing transformer, the output of which electrically connected to the third connector, laid along the screen surface of the lower receiving magnetic antenna, the end elements of the antenna reduction and the metal base symmetrically with respect to the center section of the core of the lower receiving magnetic antenna, and the shielding shells of the third screened lines of the receiving electric antenna are electrically connected to the screen of the lower receiving magnetic antenna, end reduction elements and a metal base, further comprises a fourth balancing t transformer, fourth connector, fourth shielded communication lines, a receiving magnetic loop antenna consisting of four flat identical sections of a multi-turn shielded coil with an annular gap in the screen of each flat section, identical flat sections of a multi-turn shielded coil are axially symmetrically in the same plane around the central axis of the device, each flat section of a multi-turn shielded coil is located above the corresponding flat segment of the upper metallic the receiving electrode of the receiving electric antenna, the turns of each section and all flat sections of the multi-turn shielded coil are electrically connected in series, forming a winding of the receiving frame magnetic antenna, the receiving frame magnetic antenna is separated from the upper metal electrode of the receiving electric antenna by a flat dielectric core with a central hole, to the winding of the receiving the core magnetic antenna is connected to the veins of the fourth shielded lines that electrically connect this winding to by the differential input of the fourth balancing transformer, the output of which is electrically connected to the fourth connector, the fourth shielded communication lines are laid along the surface of the electric screen of the lower receiving magnetic antenna on the rod ferrite core, the end elements of the antenna reduction and the metal base symmetrically with respect to the central section of the core of the lower receiving magnetic antenna, and the shielding shells of the fourth shielded communication lines are electrically connected to the ele an insulating screen shielded multiturn coil receiving magnetic loop antenna, an electric screen lower receiving antenna magnetic ferrite rod core, the end elements of the antenna and reducing the metal base.

In FIG. 1-3, three projections of a general view of an antenna device are presented: front view, side view, and top view, respectively. In the drawings, the following notation:

1 - upper receiving magnetic antenna;

2 - lower receiving magnetic antenna;

3 - rod ferrite core of the upper receiving magnetic antenna;

4 - rod ferrite core of the lower receiving magnetic antenna;

5 - winding of the upper receiving magnetic antenna;

6 - winding of the lower receiving magnetic antenna;

7 - electric screen of the upper receiving magnetic antenna;

8 - electric screen of the lower receiving magnetic antenna;

9 - longitudinal slots in the electric screens of the upper and lower receiving magnetic antennas;

10 - end elements of the antenna reduction;

11 - metal base;

12 - first and second shielded communication lines;

13 - shielded case of balancing transformers;

14 - connectors of the receiving magnetic antennas;

15 - receiving electric antenna;

16 - the upper metal electrode of the receiving electric antenna;

17 - lower metal electrode of the receiving electric antenna;

18 - flat segments of the upper metal electrode of the receiving electric antenna;

19 - flat segments of the lower metal electrode of the receiving electric antenna;

20 - third shielded communication lines;

21 - connector receiving electric antenna;

22 - receiving loop magnetic antenna;

23 - multi-turn shielded coil of the receiving frame magnetic antenna;

24 - flat sections of a multi-turn shielded coil;

25 - annular slots in the screen of the flat sections of a multi-turn shielded coil;

26 - flat dielectric gasket with a Central hole;

27 - fourth shielded communication lines;

28 - connector receiving frame magnetic antenna.

The compact broadband four-component receiving antenna device contains two crosswise upper and lower receiving magnetic antennas 1 and 2, which include rod ferrite cores 3 and 4, windings 5 and 6, and electric shields 7 and 8 of the upper and lower receiving magnetic antennas 1 and 2, respectively. The electric shields 7 and 8 have longitudinal slots 9, the longitudinal slit 9 of the electric screen 7 being located above the upper face of the core ferrite core 3, i.e. facing up, and the longitudinal slit 9 of the electric screen 8 is under the lower face of the core ferrite core 4, i.e. facing down. The electric screen 8 of the lower receiving magnetic antenna 2 has end elements 10 of the antenna reduction on the metal base 11. The electric screens 7, 8 of the lower and upper receiving magnetic antennas 1 and 2 and the metal base 11 are electrically connected to each other. The first and second shielded communication lines 12, consisting of two equal segments of the same type of coaxial cables, the upper and lower receiving magnetic antennas 1 and 2, are connected at one end to the differential outputs of windings 5 and 6, and the other to the differential inputs of the first and second balancing transformers (on Fig. 1-3 are not shown) located in a shielded housing 13, the outputs of which are electrically connected to the first and second connectors 14 of the upper and lower receiving magnetic antennas 1 and 2. The first and second shielded communication lines 12 ve The top and bottom receiving magnetic antennas 1 and 2 are separated in pairs, symmetrically relative to the intersection of the electric screens 7 and 8 and laid along the upper plane of the electric screen 8, the end elements 10 of the antenna reduction and the surface of the metal base 11 along the axial projection line of the lower receiving magnetic antenna 2 to projection points of the center of intersection of the upper and lower receiving magnetic antennas 1 and 2 on the metal base 11, while the shielding shells of the first and second shielded communication lines 12 along the line x gaskets are electrically connected to the electric shield 8 and the metal base 11. Above the upper receiving magnetic antenna 1 is placed the upper metal electrode 16 of the receiving electric antenna 15 of the capacitor type, consisting of four flat segments 18 axially symmetrically located in one plane around the central axis of the device, and under the lower receiving magnetic antenna 2 there is a lower metal electrode 17 of the receiving electric antenna 15 of the capacitor type, consisting of four flat segments 19, the projections of which onto the metal base 11 do not extend beyond its limits, axially symmetrically located in one plane around the central axis of the device. The flat segments 18 of the upper metal electrode 16 and the flat segments 19 of the lower metal electrode 17 are electrically electrode-connected to each other at common points lying on the central axis of the device. To the common points of the upper and lower metal electrodes 16 and 17 are connected the veins of the third shielded communication lines 20, consisting of two equal segments of the same coaxial cables, electrically connecting the receiving electric antenna 15 with the differential input of the third balancing transformer (not shown in Fig. 1-3) placed in a shielded housing 13, the output of which is electrically connected to the third connector 21 of the receiving electric antenna 15. The third shielded communication lines 20 of the receiving electric antenna 15 ra symmetrically arranged relative to the intersection of the electric screens 7 and 8 of the upper and lower receiving magnetic antennas 1 and 2 and laid along the upper plane of the electric screen 8, the end elements 10 of the antenna reduction and the surface of the metal base 11 along the axial line of the lower receiving magnetic antenna 2 to the center projection point the intersection of the upper and lower receiving magnetic antennas 1 and 2 on the metal base 11, while the shielding shells of the third shielded communication lines 20 of the receiving electric antenna 15 along l paths of their laying are electrically connected to the electric shield 8 and the metal base 11. Above the upper metal electrode 16 of the receiving electric antenna 15 there is a receiving frame magnetic antenna 22, consisting of four identical flat sections 24 of a multi-turn shielded coil 23 with an annular gap 25 in the screen of each flat sections 24, flat identical sections 24 of a multi-turn shielded coil 23 are located axially symmetrically in one plane around the central axis of the device, each plane I section 24 of a multi-turn shielded coil 23 is located above the corresponding flat segment 18 of the upper metal electrode 16 of the receiving electric antenna 15, the turns of each flat section 24 and all flat sections of the multi-turn coil 23 are electrically connected in series, forming a winding of the receiving frame magnetic antenna 22, spatially receiving the frame magnetic antenna 22 is separated from the upper metal electrode 16 of the receiving electric antenna 15 by a flat dielectric strip 26 from the center the cores of four shielded communication lines 27, electrically connecting this winding to the differential input of the fourth balancing transformer located in the shielded case 13, the output of which is electrically connected to the fourth connector 28, the fourth shielded communication lines 27 are connected to the winding of the receiving loop antenna antenna 22 along the surface of the electric screen 8 of the lower receiving magnetic antenna 2 on the rod ferrite core 4, end elements 10 of the antenna reduction and m of the threaded base 11 is symmetrical with respect to the central section of the core 4 of the lower receiving magnetic antenna 2, and the shielding shells of the fourth shielded communication lines 27 are electrically connected to the electric screen of the multi-turn shielded coil 23 of the receiving frame magnetic antenna 22, by the electric screen 8 of the lower receiving magnetic antenna 2 on the rod ferrite core 4, the end elements 10 of the antenna reduction and the metal base 11.

The device operates as follows.

The magnetic component of the electromagnetic field incident on the upper and lower receiving magnetic antennas 1, 2 is concentrated by rod ferrite cores 3, 4, respectively, and induces 5 and 6 emfs in the windings, which depend on the azimuthal angle of arrival of the electromagnetic wave and characterize the horizontal component of the magnetic fields. These emfs in the form of corresponding voltages at the symmetric outputs of the windings 5, 6, the first and second shielded communication lines 12 are transmitted to the inputs of the first and second balun transformers located in the shielded housing 13, where they are freed from common-mode interference signals, and then from the first and second receiving connectors 14 magnetic antennas 1 and 2, a pair of useful signals via cables is transmitted to the input of the receiving electronic device (recorder). To protect the windings 5, 6 from the influence of the electric component of the electromagnetic field, which is an interference factor for the upper and lower receiving magnetic antennas 1 and 2, they are placed in the electric screens 7 and 8, respectively. The electric field, interacting with the electric shields 7 and 8, forms a bias current flowing onto them from the surrounding space, which passes into the antenna drop current, flowing down from the electric shields 7, 8 from the place of their electrical connection along two symmetrical drop branches formed by two electrically and structurally identical end elements 10 of the antenna reduction, to the metal base 11. From the metal base 11, the reduction current flows through the electrophysical contact with it underlying surface of the earth. In this case, the symmetrical drainage branches formed by the antenna reduction end elements 10 on the metal base 11 of the decrease current are located in the vertical spatial fixation plane of the lower receiving magnetic antenna 2 symmetrically with respect to the orthogonal vertical plane in which the upper receiving antenna 1 is fixed. Such a spatial structure of the antenna elements the device displays the lower receiving magnetic antenna 2 from the area of the magnetic field of the decrease current, and for the upper to it of the receiving magnetic antenna 1, the influence of the oppositely directed magnetic fields of the symmetrical branches of the reduction current is compensated. The longitudinal slots 9 in the electric shields 7 and 8, located at the upper receiving magnetic antenna 1 from the top, and at the lower receiving magnetic antenna 2 from the bottom, are outside the paths of the drain current and, therefore, do not create asymmetries in its distribution. The longitudinal axes of the upper and lower receiving magnetic antennas 1 and 2 are parallel to the metal base 11. The parallelism of the planes in which the axes of the upper and lower receiving magnetic antennas 1 and 2 lie exclude the possibility of an asymmetric leakage current from the surrounding space to the antenna device. The electric component of the electromagnetic field incident on the capacitor type receiving electric antenna 15 creates between the upper metal electrode 16 of the capacitor type receiving antenna 15 and the lower metal electrode 17 of the capacitor type receiving electric antenna 15 emf, which in the form of a corresponding voltage between the cores third shielded communication lines 20 is transmitted through them to the differential input of the third balancing transformer located in the shielded box puse 13, where it is freed from the common mode interfering signal, and in the form of a useful signal from the third connector 21 of the receiving electric antenna 15 is transmitted via cable to the input of the receiving electronic device. The distance between the upper 16 and lower 17 metal electrodes is determined by the position of the flat segments 18 relative to the flat segments 19 and determines the sensitivity of the receiving electric antenna 15 of the capacitor type and, accordingly, the value of the useful signal recorded from the third connector 21 of the receiving electric antenna 15. Segmentation of the upper and lower metal flat electrodes 16 and 17 allows the receiving electric antenna 15 of the capacitor type to function without changing the characteristics of the upper and lower receiving magnetic antennas 1 and 2. The shape of the flat segments 18 and 19 practically does not affect the characteristics of the receiving electric antenna 15 of the capacitor type, only their area matters, so that the upper 16 and lower 17 metal electrodes consisting of the flat segments 18 and 19 form a flat capacitor that fits into the transverse dimensions of the metal base 11. In the receiving electronic device, useful signals from the upper and lower receiving magnetic antennas 1, 2 and the receiving electric antenna 15 of the capacitor type are analyzed I according to the ratio of their polarities, for example, the first quasi-half-period, after which a clear azimuthal direction to the source of electromagnetic radiation is given. The vertical component of the magnetic component of the electromagnetic field incident on the receiving magnetic loop antenna 22 from a source raised above the underlying surface induces an emf in the antenna winding 22, depending on the angle of the direction of arrival of the electromagnetic wave. This emf in the form of the corresponding voltage at the symmetrical terminals of the winding formed by the series electrical connection of the turns in four flat sections 24 and the sections 24 of the shielded coil 23 themselves, it is transmitted through the fourth shielded communication lines 27 to the input of the fourth balun transformer located in the shielded case 13, where they are freed from common-mode interference signals, and then from the connector 28 of the receiving frame magnetic antenna 22, the useful signal is transmitted via cable to the input of the receiving electronic device state. A flat dielectric gasket 26 with a central hole for wiring the fourth shielded communication lines 27 is designed for galvanic separation of the planes in which the receiving electric antenna 15 and the receiving frame antenna 22 are located. To protect the windings of the receiving frame magnetic antenna 22 from the electric component of the electromagnetic field, all four flat sections of a multi-turn coil 23 are placed in an electric screen with an annular slot 25 in the screen of each of these sections to eliminate interference the influence of local gradients of the electric field. In the receiving electronic device, the useful signal from the receiving frame magnetic antenna 22 corresponding to the vertical component of the magnetic component of the electromagnetic field is compared, for example, by the magnitude of the first quasi-half-period, with the calculated value of the signal corresponding to the horizontal component of the magnetic component of the electromagnetic field obtained using the useful signals of the receiving magnetic antennas 1, 2, after which the magnitude of the signals of the vertical and horizontal components of the magnetic field computes The elevation angle in the direction of the electromagnetic radiation source.

A quantitative assessment of the obtained technical result can be performed as follows.

In the case of a raised source of electromagnetic radiation, an external time-varying magnetic field H = H (t) induces currents in the windings of mutually orthogonally located “horizontal” receiving magnetic antennas 1 and 2 and the winding of the “vertical” receiving magnetic antenna 22 (wideband reception) that create on the differential inputs of the corresponding balancing transformers voltage U ₁ , U ₂ and U ₃ respectively

where K _CR1 , K _CR2 and K _CR3 are the coefficients of the conversion of the magnetic field into voltage at the loads of the receiving magnetic antennas 1, 2 and 22, respectively;

θ, ϕ — elevation angles and azimuthal directions of the vector of the magnetic component of electromagnetic radiation from a source raised above the underlying surface.

вектора напряженности магнитного поля

, равноFrom (1), (2) for the “horizontal” receiving magnetic antennas 1 and 2 it follows that with vector addition the total voltage correlated with the module of the horizontal component

magnetic field vector

equals

and does not depend on the azimuthal angle ϕ with the equality of K _CR1 and K _CR2 , i.e. The theoretically proposed device, like the prototype [3], has a strictly circular radiation pattern on the underlying surface and can be used independently of other similar devices in low-base (single-point) direction finders.

In this case, the azimuthal direction of the vector of the magnetic component of the electromagnetic field according to the results of recording the voltages U ₁ and U ₂ from mutually orthogonal receiving magnetic antennas 1, 2 is determined using the relation

в горизонтальной плоскости оставляет неопределенность в направлении на источник излучения (пеленг) ϕ_пел, допуская два диаметрально противоположенных его значения, т.е.The angle ϕ found from relation (5) corresponding to the position of the vector

in the horizontal plane leaves uncertainty in the direction of the radiation source (bearing) ϕ _sang , assuming two diametrically opposite values, i.e.

To eliminate this ambiguity of the bearing, it is necessary to find the direction of the horizontal component of the vector indicating the direction of arrival of the flow of electromagnetic energy (Poiting vector)

and determine the bearing as the opposite direction

в азимутальной плоскости найдено направление вертикальной компоненты вектора электрического поля

, нормальной к азимутальной плоскости. Поскольку продольные оси взаимно ортогональных верхней и нижней приемных магнитных антенн 1 и 2 компланарны металлическому основанию 11, устанавливаемому в азимутальной плоскости, то соответственно приемная электрическая антенна 15 должна обладать избирательной чувствительностью к компоненте электрического поля, нормальной к металлическому основанию 11. Это требование выполняется, благодаря параллельному расположению плоских сегментов 18 и 19, составляющих верхний 16 и нижний 17 металлические электроды приемной электрической антенны 15, и металлического основания 11. В результате плоские верхний 16 и нижний 17 металлические электроды образуют приемную электрическую антенны 15 конденсаторного типа с действующей высотой, равной приблизительно расстоянию между верхней и нижней плоскостями электродов 16 и 17. Внешнее изменяющееся во времени электрическое поле Е=E(t) наводит между металлическими электродами 16 и 17 приемной электрической антенны 15 э.д.с., которая создает на дифференциальном входе соответствующего симметрирующего трансформатора напряжение U₄ As follows from (6), a bearing is uniquely determined if, in addition to the direction of the horizontal component of the magnetic field vector

in the azimuthal plane, the direction of the vertical component of the electric field vector is found

normal to the azimuthal plane. Since the longitudinal axes of the mutually orthogonal upper and lower receiving magnetic antennas 1 and 2 are coplanar to the metal base 11 mounted in the azimuthal plane, respectively, the receiving electric antenna 15 must have selective sensitivity to the electric field component normal to the metal base 11. This requirement is fulfilled due to a parallel arrangement of the flat segments 18 and 19 constituting the upper 16 and lower 17 metal electrodes of the receiving electric antenna 15, and metal base 11. As a result, the flat upper 16 and lower 17 metal electrodes form a receiving electric antenna 15 of a capacitor type with an effective height equal to approximately the distance between the upper and lower planes of the electrodes 16 and 17. The external time-varying electric field E = E (t) induces between the metal electrodes 16 and 17 of the receiving electric antenna 15 emf, which creates a voltage U ₄ at the differential input of the corresponding balancing transformer

where K _CR4 - the conversion coefficient of the electric field into voltage at the load of the receiving electric antenna 15.

, и поэтому полярность напряжения U₄ по отношению к сочетанию полярностей напряжений U₁ и U₂ дает направление горизонтальной компоненты вектора Пойтинга, снимает двузначность и позволяет однозначно определить пеленг по азимутальному углу.From (7) it can be seen that the voltage U _{4 is} proportional to the vertical component of the electric field vector on the ground

, and therefore, the polarity of the voltage U ₄ with respect to the combination of the polarity of the voltages U ₁ and U ₂ gives the direction of the horizontal component of the Poiting vector, removes the ambiguity and allows you to unambiguously determine the bearing by the azimuthal angle.

The bearing along the elevation angle θ _sang , taking into account the fact that all sources of electromagnetic radiation are in the upper half-space relative to the earth’s surface, is determined unambiguously based on the relations (1), (2), (3) characterizing the three components of the magnetic field vector, and (four)

To reduce the error in determining the bearing by elevation, as can be seen from expression (8), it is necessary to equate the conversion coefficients of all three receiving magnetic antennas 1, 2 and 22 of the proposed device. With regard to magnetic antennas 1, 2, this has already been done in the prototype [3], therefore, it is necessary to ensure the maximum approximation of the conversion coefficient of the magnetic antenna 22 to the conversion coefficients of the magnetic antennas 1 and 2. The condition for achieving this goal is to maintain the equality of flux linkages Ψ in the induction magnetic antennas of various constructional execution at some reference intensity N _op external magnetic field, i.e.

where W _1,2 , W ₃ - the number of turns in the windings of the magnetic antennas 1, 2 and 22, respectively;

S _1,2 = μ _eff ⋅S _eff is the effective cross-sectional area of antennas 1, 2, in which the magnetic flux associated with these antennas is localized;

μ _eff is the effective relative magnetic permeability of the core ferrite cores 3 and 4 of the receiving magnetic antennas 1 and 2, respectively;

S _eff is the cross-sectional area of the core ferrite cores 3 and 4;

S ₃ - the total area of four flat sections 24 multi-turn shielded coil 23, forming a winding of the receiving magnetic antenna 22.

Now, to ensure the equality of these conversion coefficients, it is enough to find the functional parameter W ₃ from relation (9) that does not affect the structural and technical solution of the proposed device

The receiving magnetic loop antenna 22 is inscribed in the design of the prototype [3] with practically no increase in its overall dimensions, therefore, the dimensions of the proposed four-component device are the smallest possible for fixed sensitivity, broadband and device functionality — any constructive isolation of the receiving magnetic loop antenna 22 in an independent antenna element increases the dimensions receiving antenna system. The compactness of the proposed device gives it a finished look, makes it more convenient to use and significantly expands the scope of its application.

Thus, the claimed technical result is achieved, namely, the compact broadband four-component receiving antenna device allows the bearing to be taken along the elevation along with the bearing along the azimuthal angle to determine the location of the raised sources of electromagnetic radiation. This happens without a noticeable increase in its dimensions in comparison with the prototype.

Literature

1. US patent US 6570543 B1, IPC H01Q 7/04, 05/27/2003.

2. Akhmedzyanov I.Sh., Molochkov V.F. Broadband two-component antenna device, RF Patent No. 2474014, IPC H01Q 7/04, 06, 01/27/2013.

3. Gerasimchuk OA, Kulik MG, Molochkov VF, Neustruev VV Compact broadband three-component receiving antenna device, RF patent No. 2573180, IPC H01Q 7/00, 01/20/2016.

Claims (1)

A compact broadband four-component receiving antenna device containing a metal base, on which there are two mutually orthogonal receiving magnetic antennas on rod ferrite cores, located crosswise, with windings on each of the cores symmetrically relative to the central sections of the cores, the first and second balancing transformers, the first and second second connectors, differential leads of the windings are electrically connected to the differential inputs respectively balancing transformers, and the outputs of the first and second balancing transformers are electrically connected to the corresponding connectors, the electric screens of the receiving magnetic antennas with longitudinal slots, the first and second shielded communication lines, the end elements of the antenna reduction, the receiving magnetic antennas are offset vertically relative to each other, are located above a metal base, the plane of which is parallel to the longitudinal axes of the receiving magnetic antennas, the windings of each of the receiving magnetic antennas The electric screens of the upper and lower receiving magnetic antennas are electrically connected to each other in their own electric screen with a longitudinal slit, at the intersection of the antennas, the longitudinal slit of the screen of the upper receiving magnetic antenna is facing up, the longitudinal slit of the screen of the lower receiving magnetic antenna is facing down, to the end the edges of the screen of the lower receiving magnetic antenna are symmetrically electrically connected electrically conductive structurally identical end elements of the antenna reduction, closing electric screens on the metal base, and the first and second shielded communication lines between the differential outputs of the receiving magnetic antennas and the differential inputs of the balancing transformers are laid along the surfaces of the screen of the lower receiving magnetic antenna, the end elements of the antenna reduction and the metal base symmetrically with respect to the central section of the core of the lower receiving magnetic antenna, and the shielding shells of the first and second shielded communication lines are electrically connected to the crane of the lower receiving magnetic antenna, the end elements of the antenna reduction and the metal base, the third balancing transformer, the third connector, the third shielded communication lines, the upper and lower metal electrodes, consisting of four flat segments, the projections of four flat segments on a metal base do not go beyond , four flat segments are axially symmetrically located in one plane around the central axis of the device and are electrically connected to each other at a common point lying d on the central axis of the device, and the plane of the upper electrode is located above the upper receiving magnetic antenna, and the plane of the lower electrode is located below the lower receiving magnetic antenna, and both electrodes form a receiving electric antenna of the capacitor type, to the common points of each electrode of which are connected the conductors of the third shielded communication lines electrically connecting the electrodes to the differential input of the third balancing transformer, the output of which is electrically connected to the third connector, laid along the surface of the screen of the lower receiving magnetic antenna, the end elements of the antenna reduction and the metal base are symmetrical with respect to the central section of the core of the lower receiving magnetic antenna, and the shielding shells of the third screened lines of the receiving electric antenna are electrically connected to the screen of the lower receiving magnetic antenna, the end reduction elements and the metal base characterized in that it further comprises a fourth balancing transformer, a quarter a fourth connector, fourth shielded communication lines, a receiving magnetic loop antenna, consisting of four flat identical sections of a multi-turn shielded coil with an annular gap in the screen of each flat section, identical flat sections of a multi-turn shielded coil are axially symmetrically in the same plane around the central axis of the device, each the flat section of the multi-turn shielded coil is located above the corresponding flat segment of the upper metal electrode of the receiving ele ctric antenna, turns of each section and all flat sections of a multi-turn shielded coil are electrically connected in series, forming a winding of the receiving frame magnetic antenna, the receiving frame magnetic antenna is separated from the upper metal electrode of the receiving electric antenna by a flat dielectric core with a central hole, to the winding of the receiving frame magnetic antennas are connected to the veins of the fourth shielded lines, electrically connecting this winding with a differential input m of the fourth balancing transformer, the output of which is electrically connected to the fourth connector, the fourth shielded communication lines are laid along the surface of the electric screen of the lower receiving magnetic antenna on the rod ferrite core, the end elements of the antenna reduction and the metal base are symmetrical with respect to the central section of the core of the lower receiving magnetic antenna, and shielding the shells of the fourth shielded communication lines are electrically connected to the electric screen govitkovoy shielded coil receiving magnetic loop antenna, an electric screen lower receiving antenna magnetic ferrite rod core, the end elements of the antenna and reducing the metal base.

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