RU2409880C1 - Antenna - Google Patents

Abstract

FIELD: radio engineering. ^ SUBSTANCE: antenna includes SSL section formed with two similar metal plates which are connected to each other with short-circuiter on one side, and section of signal strip line, which are located between surfaces of one and the other insulating substrates, antenna aperture is formed with the section of divergent symmetric slot line (SSL) which is the continued part of the section of homogeneous symmetric slot line, and similar metal plates forming it are convergent along inner side edge from the area of the beginning of enlargement of the section of symmetric slot line to maximum antenna aperture; at that, on one side the section of signal strip line is connected to channelling transmission line; its earth surface is one and the other metal plates of the section of homogeneous symmetric slot line. The first and the second additional insulating substrates are introduced, which are identical to one and the other insulating substrates. Metal plates along external side edge of the section of symmetric slot line are parallel relative to its longitudinal symmetry axis. ^ EFFECT: development of broad-band antenna capable of radiating and receiving longitudinal electromagnetic waves with low level of irregularity of matching characteristic, and simple and high-technology design. ^ 37 cl, 36 dwg

Description

The invention relates to the field of radio engineering, in particular to ultra-wideband printed antennas of the microwave range, and can find application in communication systems, in radio defectoscopy, in problems of radio monitoring, in problems of electromagnetic compatibility of radio systems, as part of phased array antennas, in metrology, in medicine for electromagnetic applicators and in problems of hyperthermia.

Known ultra-wideband antenna (US patent No. 5278575, class MKI H01Q 9/28, NCI 343/795, publ. 01/11/1994), made on the basis of a printed antipodal slit line (ASL). The antenna aperture is formed by an ASL segment without overlapping and contains two identical metal plates located on different sides of the dielectric substrate, one above the other. In the radiating part of the antenna, the metal plates of the ASL are made exponentially expanding along the inner lateral edge from the point of zero overlap to the maximum aperture opening. The recording signal conductor of the microstrip transmission line segment with the end face is galvanically connected to the inner side edge of one ASL metal plate in the area of zero overlap, and its earth plane is galvanically connected to the end side edge of another ASL metal plate in the region of zero overlap.

A disadvantage of the known device is that it only receives transverse electromagnetic waves.

The closest technical solution to the prototype is a transceiver antenna (DE patent No. 3941125, IPC H01Q 13/10, publ. 06/20/1991), containing two identical dielectric substrates, one surface mounted on top of one another, and two identical, shorted at one end of a segment of a symmetrical slotted line (BFL), consisting of a segment of a homogeneous symmetrical slotted line (BFBF) and a segment of an expanding BFL, located on the outer surface of one and the other dielectric substrates, respectively, while on the alignment surface a segment of the signal strip line is located between one and the other dielectric substrates, for which the ground surfaces are metal plates of two segments of the OSL, thereby forming a segment of a symmetrical shielded strip line, with one end of the signal strip conductor intersecting the segment of one and the other ASL at right angles, and the other the end of the signal strip conductor is connected to the channel transmission line. The antenna aperture is formed by a segment of expanding AHL in the direction from the area of connection with a segment of AHL to the area of maximum aperture, and the identical metal plates forming it are made tapering along the inner lateral edge from the area of the beginning of expansion of AHL to the area of maximum aperture.

The main disadvantage of this solution is that it provides radiation and reception of transverse electromagnetic waves and cannot generate radiation and reception of longitudinal electromagnetic waves.

The technical task of this invention is to provide a broadband antenna capable of emitting and receiving longitudinal electromagnetic waves with a low level of uneven matching characteristics, a simple and high-tech design.

The problem is achieved in that in an antenna containing a segment of the SSD formed by two identical metal plates that are connected to each other by a short circuit, and a segment of the signal strip line, which are located between the surfaces of one and the other dielectric substrates, the aperture of the antenna is formed by a segment of expanding symmetrical slotted line, which is a continuation of a segment of a homogeneous symmetrical slotted line, and the same metal plates forming it tapering along the inner lateral edge from the region of the beginning of the expansion of the segment of the symmetrical slotted line to the region of the maximum aperture of the antenna aperture, while on one side the segment of the signal strip line is connected to the canalizing transmission line, its ground surface is one and the other metal plates of the segment of a uniform symmetrical slotted line , according to the proposed solution, the segment of the signal strip line is located in the plane of the segment of a homogeneous symmetrical slot line between one and with other metal plates forming it, and the longitudinal axis of symmetry of a signal strip line segment is aligned with the longitudinal axis of symmetry of a segment of a homogeneous symmetrical slot line, while on the other hand, the signal strip line segment is connected to an exciting element made in the form of a segment of an axisymmetric metal conductor, the longitudinal axis of symmetry which is combined with the longitudinal axis of symmetry of the signal strip line segment.

Also, the first and second additional dielectric substrates can be introduced into the antenna, identical to one and the other dielectric substrates, between which there is a segment of an additional symmetrical slot line formed by two additional identical metal plates that are connected to each other on one side by an additional short circuit, and a segment of an additional signal strip line, which from the location in the area of the aperture of the antenna is connected to an additional exciting a element located coaxially with an additional segment of a homogeneous symmetrical slotted line, wherein a second additional dielectric substrate is symmetrically mounted on the surface of the first additional dielectric substrate, and on the other hand, a segment of the signal strip line and a segment of the additional signal strip line are galvanically connected to each other by a contact element, and a short circuit and an additional short circuit are galvanically interconnected by a common short circuit.

In the antenna, one and the other dielectric substrates, or one and the other dielectric substrates and the first and second additional dielectric substrates in the region of the antenna aperture can be made with a relative permittivity in the region of the antenna aperture equal to unity, or with the same relative permittivity and the same thickness, which ensures complete symmetry with respect to the plane of the location of the alkali metal core.

The antenna can be made with the width of all dielectric substrates equal to the width of the maximum aperture opening or more.

The antenna can be made with galvanic connection to each segment of the ASC, in the area of the maximum aperture of the aperture of the antenna, the aperture segment of the ASCL, the width of which is equal to the width of the segment of the expanding ASC in the area of the maximum aperture of the aperture of the antenna, while the inner side edges of the aperture segment of the ASCL are parallel to the axis of symmetry of the ASC .

The antenna can be made with the location in the area of each aperture segment OSL, at least one director, made in the form of a metal conductor, for example strip, located symmetrically relative to the inner side edges of the aperture segment OSL and perpendicular to its longitudinal axis of symmetry.

The narrowing of the metal plates along the inner lateral edge of the SHL segment in the region of the antenna aperture along its longitudinal axis of symmetry, in the direction from the connection region with the SHL segment to the region of the maximum aperture of the antenna aperture, can be described by a linear or nonlinear function.

The metal plates along the outer lateral edge along the longitudinal axis of symmetry of the SHL segment can be made parallel, or can be made identically tapering or expanding in the direction from the connection region with the corresponding segment of a homogeneous symmetrical slot line to the region of maximum aperture of the antenna aperture, while the law of narrowing or expansion metal plates is described by a linear or nonlinear function.

The antenna can be made with two identical axisymmetric metal radiating plates, which are mounted symmetrically with respect to the plane of the location of the symmetrical slot line segment and are galvanically connected along their entire length in the aperture area of the antenna along the inner side edges of the metal plates of the expanding symmetric slot line.

Metal radiating plates can be made along their longitudinal axis of symmetry with a length equal to the length of the inner lateral edge of the segment of the expanding alkalinity.

Metal radiating plates can be made along their longitudinal axis of symmetry of constant width, and the plate itself, for example, in the form of a rectangle or increasing width in the direction from the region of the beginning of the extension of the segment of the ACL to the region of the maximum aperture of the antenna aperture, and its increase in width is described by a linear or nonlinear function .

A nonlinear function may look like:

y = ax ^{± m / n} ,

where a is the coefficient, is given by a real number;

m, n are positive integer coprime numbers, with n> m;

x is the coordinate corresponding to the longitudinal axis of symmetry of the metal radiating plate.

Also, a nonlinear function can take the form:

y = ae ^bx + ce ^dx ,

where a, b, c, d are coefficients, are given by real numbers;

x is the coordinate corresponding to the longitudinal axis of symmetry of the metal radiating plate.

The metal conductors of the exciting elements of the antenna can be made in the form of a rectangular plate or in the form of a plate expanding along two external lateral edges along the longitudinal axis of symmetry of the ACL segment in the direction from the region of the connection with the signal strip line to the region of maximum aperture aperture, and the expansion law is described linear or non-linear function.

The antenna can be made by installing on one and the other external side edges, extended along the longitudinal axis of symmetry, the metal plate of the exciting element, at least one pair of identical planar matching elements, respectively, one on one and the other external side edge.

The planar matching element can be made of at least one impedance loop in the form of a ribbon conductor, which is galvanically connected to the outer side edge of the plate of the metal conductor of the exciting element.

Also, the planar matching element can be made of at least one homogeneous or inhomogeneous impedance loop, which can be connected to the outer lateral edge of the plate of the metal conductor of the exciting element galvanically or electromagnetically in the form of a uniform or inhomogeneous gap.

In the antenna between the segment of the signal strip line and the metal conductor of the exciting element, an adapter can be connected coaxially.

The transition device can be made: in the form of an axisymmetric strip conductor; in the form of a gap between the end of the signal strip line segment and the end of the conductor of the exciting element; or in the form of a semiconductor element with an electrically adjustable capacitance included in the gap.

The antenna can be made with the introduction of two identical axisymmetric metal impedance plates that are mounted on the side of the outer lateral edges of the metal plates of the SCL segment, symmetrically with respect to the longitudinal axis of symmetry of the plane of the arrangement of the metal plates of the SCL and perpendicular to this plane, each metal impedance plate being identically galvanically connected by a contact element with appropriate metal plate.

The width of the metal impedance plate from the region of the maximum aperture to the region of the minimum aperture of the antenna can be the same, and the plate itself, for example, in the form of a rectangle, or increasing or decreasing width, and a change in the width of the metal impedance plate can be described by a linear or nonlinear function.

The contact element can be made in the form of a metal rod of a round or rectangular profile and can be installed both in the region of the maximum aperture opening and anywhere in the segment of the outer lateral edge of the metal plates forming a segment of expanding SCL.

Also, the contact element can be made, for example, in the form of a ribbon conductor, which is installed along the outer lateral edges of the metal plates of a section of expanding SCL.

Also, the contact element can be made, for example, in the form of a semiconductor element, with an electrically adjustable capacitance, or, for example, in the form of an inductance coil in a volumetric or planar design, also installed on the outer lateral edges of metal plates, a segment of an expanding SHL.

In addition, a nonlinear function may have the form:

y = ax ^{± m / n} ,

where a is the coefficient, is given by a real number;

m, n are positive integer coprime numbers, with n> m;

x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line.

Also, a nonlinear function can take the form:

y = ae ^bx + ce ^dx ,

where a, b, c, d are coefficients, are given by real numbers;

x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line.

Figure 1 shows the design of the antenna; figure 2 shows the design of the antenna (figure 1) with two additional dielectric substrates, an additional segment of the SCL and an additional exciting element; figure 3 and figure 4 shows a longitudinal section of the antenna (figure 1) in the plane of the location of the segment AH with a width of dielectric substrates equal to the width of the maximum aperture of the aperture of the antenna and greater than the width of the maximum aperture of the aperture of the antenna, respectively, and with a linear narrowing of the metal plates along the inner side edge; figure 5 shows a longitudinal section of the antenna (figure 4) with an aperture segment OSPL connected in the area of maximum aperture aperture; figure 6 shows a longitudinal section of the antenna (figure 5) with the director installed in the region of the aperture segment OSCHL, made in the form of a conductor of rectangular shape; in Fig.7 and Fig.8 depicts a longitudinal section of the antenna (Fig.1) in the plane of the segment of the alkalinity with nonlinear narrowing of the metal plates along the inner lateral edge of a convex and concave shape, respectively; Fig.9 is an example of an antenna with a narrowing of the metal plates along the outer lateral edges of a linear shape along the longitudinal axis of symmetry of the antenna in the direction from the maximum to the minimum opening aperture; figure 10 and figure 11 is an example of the antenna (Fig.9) with a nonlinear narrowing of the metal plates of a convex and concave shape, respectively; on Fig - an example of the antenna with the expansion of the metal plates on the outer lateral edges of a linear shape along the longitudinal axis of symmetry of the antenna in the direction from the maximum to the minimum opening aperture; in Fig.13 and Fig.14 is an example of an antenna (Fig.12) with non-linear expansion of the metal plates of a convex and concave shape, respectively; on Fig - an example of the antenna (Fig.1) with installed metal radiating plates on the inner side edges of the metal plates; in Fig.16 is an example of a plate of a metal conductor of the exciting element of the antenna (Fig.1) in the form of a rectangle; in Fig.17 is an example of a metal conductor of the exciting element of the antenna (Fig.1) in the form of a plate with an extension along the outer lateral edges of a linear shape; in Fig.18 and in Fig.19 is an example of a conductor of the exciting element of the antenna (Fig.1) in the form of a plate with non-linear expansion along the outer lateral edges of a concave and convex shape, respectively; in Fig.20 is an example of a planar matching antenna elements (Fig.1) made in the form of three pairs of identical impedance loops in the form of ribbon conductors, which are galvanically connected at the outer lateral edges with a plate of a metal conductor of the exciting element; in Fig.21 and Fig.22 is an example of a planar matching antenna elements (Fig.1), consisting of one pair and two pairs, respectively, of identical heterogeneous impedance loops made in the form of a triangular-shaped conductor, which are galvanically connected to external side edges with a plate of a metal conductor of the exciting element; in Fig.23 and Fig.24 is an example of a planar matching antenna elements (Fig.1), consisting of one pair of identical inhomogeneous impedance loops, which are connected by a homogeneous and inhomogeneous electromagnetic coupling, respectively, in the form of a gap along the outer lateral edges with the plate a metal conductor of the exciting element; in Fig.25 is an example of a transition device of the antenna (Fig.1) in the form of an axisymmetric ribbon conductor included between a segment of the signal strip line and the conductor of the exciting element; in Fig.26 is an example of a transition device of the antenna (Fig.1) in the form of an air gap between the end face of the signal strip line segment and the end face of the metal conductor of the exciting element; in Fig.27 is an example of a transition device of the antenna (Fig.26) in the form of a semiconductor element included in the air gap; in Fig.28 shows a longitudinal section of the antenna (Fig.1) in the plane of the location of the segment SCHL with galvanic connection of metal impedance plates through contact elements made in the form of a rod, to metal plates in the region of maximum aperture opening; in Fig. 29, a simplified longitudinal section of the antenna is shown (Fig. 1) in the plane of the segment of the SSHL with an example of galvanic connection of metal impedance plates through contact elements made in the form of a ribbon conductor, which are connected along their entire length along the outer side edges with metal plates SSCL section; in Fig.30 is an example antenna embodiment (Fig. 1) with rectangular metal impedance plates connected by contact elements in the form of a rod along the outer lateral edges of the metal plates of the SCL segment in the region of the maximum aperture opening; on Fig, on Fig, on Fig - examples of the antenna (Fig. 1) with metal impedance plates of linearly decreasing width, non-linearly decreasing width of the convex shape, non-linearly decreasing width of the concave shape, respectively, in the direction from the region of maximum to the area of the minimum aperture of the antenna aperture; in Fig.34, in Fig.35, in Fig.36 - examples of the antenna (Fig.1) with metal impedance plates of linearly increasing width, non-linearly increasing width of convex shape, non-linearly increasing width of concave shape, respectively, in the direction from the region of maximum to the area of the minimum aperture of the antenna aperture.

The antenna (Fig. 1) contains a segment of the SSHL 1, formed by two identical metal plates 2, which are interconnected on one side by a short circuit 3 and located between the surfaces of one and the other dielectric substrates 4 and 5. A segment of the signal strip line 6 is also located between the surfaces of one a dielectric substrate 4 and another dielectric substrate 5. The aperture of the antenna is formed by a segment of expanding ASCL 7, which is a continuation of a segment of ASCL 8, and the same metal plases forming it 2 ins formed by tapering the inner side edge area 9 of the beginning of expansion segment symmetric slot lines 1 to a maximum aperture area of the aperture. A segment of the signal strip line 6 is connected on one side to the channeling transmission line and, on the other hand, is connected to the exciting element 10, made in the form of a segment of an axisymmetric metal conductor, the longitudinal axis of symmetry of which is aligned with the longitudinal axis of symmetry of the segment of the signal strip line 6. The ground surface of the segment the signal strip line 6 are one and the other metal plates 2 of the segment OSCHL 8, while it is located in the plane of the segment OSCHL 8 between one and the other metal plates 2 of its generators. The longitudinal axis of symmetry of the segment of the signal strip line 6 is aligned with the longitudinal axis of symmetry of the segment OSCHL 8.

The antenna (figure 2) can be performed with the introduction of the first and second additional dielectric substrates 11 and 12, between which there is a segment of an additional SSHL 13 formed by two additional metal plates 16 that are interconnected by an additional short circuit 17. A segment of an additional SSHL 13 consists of a segment of additional OSL 14 and a segment of additional expanding SSL 15. A segment of an additional signal strip line 18 is located between the surfaces of the first and second additional dielectric substrates 11 and 12. A segment of the additional signal strip line 18 is connected on one side to the additional excitation element 19, and on the other hand is galvanically connected by the contact element 20 with a segment of the signal strip line 6. Short circuit 3 and additional short circuit 17 are galvanically interconnected by a common short circuit 21.

The antenna (Fig. 5) can be made with galvanic connection to a section of an expanding ASCL 7 in the region of the maximum aperture of the antenna of the aperture segment 22 of a section of ASCL 23, the width of which is equal to the width of an expanding SCL 7 in the region of a maximum aperture of the aperture, while the inner side edges 24 of the aperture of the segment 22 are parallel to the axis of symmetry of the segment of the expanding SCL 7 and are galvanically connected to the inner side edges 9 of the segment of the expanding SCL 7.

At least one director 25 in the form of, for example, a strip conductor located symmetrically with respect to the inner lateral edges 24 of the aperture segment 22 of the segment OSCHL 23 and perpendicular to its longitudinal axis of symmetry (FIG. 6).

The antenna (Fig.9-Fig.14) can be performed with a narrowing or expansion along the outer lateral edge 26 of the metal plates 2, forming a segment of the SCL 1 in the direction from the maximum to the minimum opening aperture of the antenna.

The antenna (Fig.15) can be performed with the introduction of two identical metal axisymmetric radiating plates 27.

The exciting element 10 may be made in the form of a plate, which has two different shapes along the two outer lateral edges 28 (Fig.16-Fig.19).

Strip matching elements 29 can be installed on the outer lateral edges 28 of the plate of the metal conductor of the exciting element 10 galvanically or electromagnetically connected in the form of a gap 30 (Fig.20-Fig.24).

A transition device 31 can be installed between the end face of the signal signal strip line 6 and the conductor of the exciting element 10 (Fig. 25-Fig. 27).

Metal impedance plates 32 can be installed using the contact element 33 along the outer lateral edges 26 of the metal plates 2 (Fig.28-Fig.36).

The proposed antenna belongs to the class of transceiver printed antennas of longitudinal waves and works as follows.

In the antenna (Fig. 1), an input microwave signal of a type-T wave enters the segment of the signal strip line 6 located symmetrically between the metal plates 2, which are, in turn, for the segment of the signal strip line 6, earth plates, i.e. the signal enters the segment of the coplanar strip line of the type-T wave. (Sachse K., Sowicki A. // New microstrip transmission lines for microwave integrated circuits. // In: IEEE Proc. Microwave Symp., 1979, p. 468-470.) To a piece of signal strip line 6 in the region of the antenna aperture, those. in the region of the segment of the expanding SCHL 1, the exciting element 10 is connected coaxially. The metal plates 2 forming the segment of the OSHL 8 and the segment of the expanding SCHL 7, due to the interconnection of the short circuit 3, are under the same potential and at the same time carry out two functions, namely earth plates in relation to the length of the signal strip line 6 and the aperture of the antenna, and the length of the signal strip line 6 is under a different potential. The area of the antenna aperture, i.e. the region of the segment of the expanding SSL 7 with the exciting element 10 having the same potential as the segment of the signal strip line 6 can be considered as two identical inhomogeneous transmission lines of the T-type transverse electromagnetic wave with a common central conductor, namely: a common conductor - a signal segment strip line 6, and two other conductors - one and the other metal plates 2 of the segment of the expanding SCL 7. The excitation element 10 on the surfaces of one and the other metal plates 2 are excited surface conductivity oxides corresponding to type-T transverse electromagnetic wave. The excited surface conduction current on the surface of each metal plate 2 in the region of the antenna aperture generates an electric field vector характеризуется, which is characterized by two components of the electric field E _□ and E _⊥ relative to the longitudinal axis of symmetry of the segment ASC 1. The first of these E _□ is parallel to the longitudinal axis of symmetry of the segment SBL 1, and the second E _⊥ is orthogonal to the longitudinal axis of symmetry of the segment SBL 1.

By virtue of symmetry, the components of the electric field E _{□ are} oriented identically and, accordingly, are summed in the aperture of the antenna, and the components of the electric field E _{⊥ are} oriented opposite and, respectively, are mutually compensated in the aperture. As a result of the summation of all the components of the electric field E _□ on the metal plates 2 of the segment of the expanding SHL 1 in the aperture, the formation and emission of a longitudinal electromagnetic wave occurs. Thus, the primary transverse electromagnetic wave is transformed into a secondary longitudinal electromagnetic wave radiated into free space.

The use of additional first and second additional dielectric substrates 11 and 12 and a segment of additional SSHL 13 (FIG. 2) for the antenna (FIG. 1) allows narrowing the radiation pattern in the H-plane and increasing the gain.

In the design of the antenna can be used various:

- the dimensions of the dielectric substrates in relation to the maximum aperture of the antenna aperture (Fig.3 and Fig.4);

- aperture segment 22 of the segment OSCHL 23, connected to the area of maximum aperture aperture (figure 5);

- Director 25, installed in the area of the aperture segment 22 of the segment OSCHL 23 (Fig.6);

- the shape of the metal plates 2 along the inner lateral edge 9 in the region of the aperture of the antenna (Fig.7 and Fig.8);

- the shape of the metal plates 2 along the outer lateral edge 26 (Fig.9-Fig.14);

- the installation of metal radiating plates 27 along the inner lateral edges 9 of the metal plates 2 of the segment SCHL 1 in the region of the antenna aperture (Fig. 15);

- forms of execution of the plates of the exciting elements 10 (Fig.16-Fig.19);

- embodiments of matching elements 29 for matching the exciting element 10 with the aperture of the antenna (Fig-20);

- types of transition devices 31, which are used to connect a segment of the signal strip line 6 with the exciting element 10 (Fig.25-Fig.27);

- options for connecting the contact elements 33 of the metal impedance plates 32 to the outer lateral edges 26 of the metal plates 2 of the segment SCHL 1 (Fig. 28 and Fig. 29);

- embodiments of the forms of metal impedance plates 32 along the outer lateral edges 34 (Fig.30-Fig.36).

The optimal selection of elements allows you to create antenna designs for a given electrical characteristics.

Claims (43)

1. An antenna containing a segment of a symmetrical slot line formed by two identical metal plates that are connected to each other by a short circuit and a segment of a signal strip line that are located between the surfaces of one and the other dielectric substrates, the antenna aperture is formed by a segment of an expanding symmetrical slot line which is a continuation of a segment of a homogeneous symmetrical slit line, and the identical metal plates forming it are made tapering about the inner lateral edge from the region of the beginning of the expansion of the segment of the symmetrical slot line to the region of the maximum aperture of the antenna aperture, while on one side the segment of the signal strip line is connected to the sewer transmission line, its ground surface is one and the other metal plates of the segment of a homogeneous symmetrical slot line, different the fact that the segment of the signal strip line is located in the plane of the segment of a homogeneous symmetrical slot line between one and the other metal layers its generators, and the longitudinal axis of symmetry of the signal strip line segment is aligned with the longitudinal axis of symmetry of the homogeneous symmetrical slot line segment, while on the other hand, the signal strip line segment is connected to an exciting element made in the form of an axisymmetric metal conductor segment whose longitudinal axis of symmetry is aligned with the longitudinal axis of symmetry of the signal strip line segment. 2. The antenna according to claim 1, characterized in that the first and second additional dielectric substrates are introduced, identical to one and the other dielectric substrates, between which there is a segment of an additional symmetrical slot line formed by two additional identical metal plates that are interconnected on one side an additional short circuit, and a segment of an additional signal strip line, which is connected to the additional excitation from the location in the area of the antenna aperture a friction element located coaxially with an additional segment of a homogeneous symmetrical slot line, while a second additional dielectric substrate is symmetrically mounted on the surface of the first additional dielectric substrate, and on the other hand, a segment of the signal strip line and a segment of the additional signal strip line are galvanically connected to each other by a contact element, and the short circuit and the additional short circuit are galvanically interconnected by a common short circuit Atelier. 3. The antenna according to claim 1 or 2, characterized in that the dielectric substrate in the region of the antenna aperture is made with a relative permittivity equal to unity. 4. The antenna according to claim 1 or 2, characterized in that the dielectric substrate is made of the same thickness and with the same relative dielectric constant. 5. The antenna according to claim 1 or 2, characterized in that the width of the dielectric substrates is equal to or greater than the width of the maximum aperture opening. 6. The antenna according to claim 1 or 2, characterized in that for each segment of the symmetrical slotted line in the region of the maximum aperture of the antenna aperture, an aperture segment of a uniform symmetrical slotted line is galvanically connected, the width of which is equal to the width of the segment of the expanding symmetrical slotted line in the region of the maximum aperture of the antenna aperture while the inner side edges of the aperture segment of a homogeneous symmetrical slot line are parallel to the axis of symmetry of the segment of the symmetric slot line. 7. The antenna according to claim 6, characterized in that at least one director is introduced in the region of the aperture segment of the homogeneous symmetrical slit line, made in the form of a metal conductor located symmetrically with respect to the inner side edges of the aperture segment of the homogeneous symmetrical slit line and perpendicular to it longitudinal axis of symmetry. 8. The antenna according to claim 1 or 2, characterized in that the narrowing of the metal plates along the inner lateral edge of a segment of a symmetrical slot line along its longitudinal axis of symmetry in the region of the aperture of the antenna in the direction from the region of connection with a segment of a uniform symmetrical slot line to the region of maximum aperture opening Antennas are described by a linear or non-linear function. 9. The antenna of claim 8, wherein the non-linear function has the form: y = ax ^{± m / n} ,
where a is the coefficient, is given by a real number;
m, n are positive integer coprime numbers, with n>m;
x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line. 10. The antenna of claim 8, wherein the non-linear function has the form: y = ae ^bx + ce ^dx ,
where a, b, c, d are coefficients, are given by real numbers;
x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line. 11. The antenna according to claim 1 or 2, characterized in that the metal plate along the outer lateral edge of a segment of a symmetrical slot line is made parallel with respect to its longitudinal axis of symmetry. 12. The antenna according to claim 1 or 2, characterized in that the metal plate along the outer lateral edge along the longitudinal axis of symmetry of a segment of a symmetrical slot line in the direction from the region of maximum aperture opening to the region of minimum aperture of the antenna is made identically tapering or expanding, and narrowing or the expansion of metal plates is described by a linear or nonlinear function. 13. The antenna of claim 12, wherein the non-linear function has the form: y = ax ^{± m / n} ,
where a is the coefficient, is given by a real number;
m, n are positive integer coprime numbers, with n>m;
x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line. 14. The antenna according to item 12, wherein the non-linear function has the form:
y = ae ^bx + ce ^dx ,
where a, b, c, d are coefficients, are given by real numbers;
x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line. 15. The antenna according to claim 1 or 2, characterized in that two identical axisymmetric metal radiating plates are introduced, which are located symmetrically relative to the plane of the corresponding segment of the symmetrical slot line and are galvanically connected along their entire length in the region of the antenna aperture along the inner lateral edges of the metal plates a segment of an expanding symmetrical slit line. 16. The antenna according to clause 15, wherein the length of the metal radiating plate along its longitudinal axis of symmetry is equal to the length of the inner side edge of the segment of the expanding symmetric slot line along its longitudinal axis of symmetry. 17. The antenna according to clause 15, wherein the width of the metal radiating plate along its longitudinal axis of symmetry is made constant, and the surface itself, for example, is rectangular in shape. 18. The antenna according to claim 15, characterized in that the width of the metal radiating plate along its longitudinal axis of symmetry, from the region of the beginning of the expansion of the segment of the symmetrical slot line to the region of the maximum aperture of the antenna aperture, is increasing, and its increase in width is described by a linear or nonlinear function. 19. The antenna according to claim 18, characterized in that the non-linear function has the form:
y = ax ^{± m / n} ,
where a is the coefficient, is given by a real number;
m, n are positive integer coprime numbers, with n>m;
x is the coordinate corresponding to the longitudinal axis of symmetry of the metal radiating plate. 20. The antenna according to claim 18, characterized in that the non-linear function has the form:
y = ae ^bx + ce ^dx ,
where a, b, c, d are coefficients, are given by real numbers;
x is the coordinate corresponding to the longitudinal axis of symmetry of the metal radiating plate. 21. The antenna according to claim 1 or 2, characterized in that the metal conductor of the exciting element is made in the form of a rectangular plate. 22. The antenna according to claim 1 or 2, characterized in that the metal conductor of the exciting element is made in the form of a symmetrical slot line extending along two external lateral edges of the plate along the longitudinal axis of symmetry in the direction from the connection region with the signal strip line segment to the maximum aperture region aperture, while the law of expansion is described by a linear or nonlinear function. 23. The antenna according to item 22, wherein the non-linear function has the form:
y = ax ^{± m / n} ,
where a is the coefficient, is given by a real number;
m, n are positive integer coprime numbers, with n>m;
x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line. 24. The antenna according to item 22, wherein the non-linear function has the form:
y = ae ^bx + ce ^dx ,
where a, b, c, d are coefficients, are given by real numbers;
x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line. 25. The antenna according to claim 1 or 2, characterized in that on one and the other outer side edges of the plate of the metal conductor of the exciting element, extended along its longitudinal axis of symmetry, at least one pair of identical planar matching elements is installed, respectively one on one and the other outer side edge. 26. The antenna according to claim 25, wherein the planar matching element is made of at least one impedance loop in the form of a ribbon conductor, which is galvanically connected to the outer side edge of the plate of the metal conductor of the exciting element. 27. The antenna according to claim 25, wherein the planar matching element is made of at least one inhomogeneous impedance loop. 28. The antenna according to item 27, wherein the inhomogeneous impedance loop is connected to the outer side edge of the plate of the metal conductor of the exciting element galvanically. 29. The antenna according to claim 27, wherein the non-uniform impedance loop is connected electromagnetically to the outer side edge of the plate of the metal conductor of the exciting element. 30. The antenna according to clause 29, wherein the electromagnetic coupling is made in the form of a uniform or non-uniform gap. 31. The antenna according to claim 1 or 2, characterized in that between the segment of the signal strip line and the metal conductor of the exciting element, the adapter is coaxially connected. 32. The antenna according to p, characterized in that the transition device is made in the form of an axisymmetric strip strip conductor. 33. The antenna according to p. 31, characterized in that the transition device is made in the form of a gap between the end face of a segment of the signal strip line and the end face of the metal conductor of the exciting element. 34. The antenna according to claim 33, characterized in that a semiconductor element with an electrically adjustable capacitance is included in the gap. 35. The antenna according to claim 1 or 2, characterized in that two identical axisymmetric metal impedance plates are introduced, which are mounted on the side of one and the other external lateral edges of the metal plates of a segment of a symmetrical slot line, symmetrically with respect to the longitudinal axis of symmetry of the plane of arrangement of the metal plates and perpendicularly this plane, with each metal impedance plate is galvanically connected by the contact element to the outer lateral edge of the metal plate. 36. The antenna according to claim 35, characterized in that the contact element is made in the form of a metal rod and is installed in the region of the maximum aperture of the antenna aperture or anywhere on the segment of the outer lateral edges of the metal plates forming a segment of an expanding symmetrical slot line. 37. The antenna according to clause 35, wherein the contact element is made in the form of a ribbon conductor, which is installed along the outer side edges of the metal plates of a segment of an expanding symmetrical slot line from the area of the maximum aperture of the antenna aperture to the area of the minimum aperture. 38. The antenna according to clause 35, wherein the contact element is made in the form of a semiconductor element with an electrically adjustable capacitance, which is mounted on the outer side edges of the metal plates of a segment of an expanding symmetrical slot line. 39. The antenna according to clause 35, wherein the contact element is made in the form of an inductance coil in volumetric or planar design, which is mounted on the outer lateral edges of the metal plates of a segment of an expanding symmetrical slot line. 40. The antenna according to claim 35, characterized in that the width of the metal impedance plate in the direction of the longitudinal axis of symmetry of the segment of the symmetrical slot line from the maximum to the region of the minimum aperture of the antenna aperture is the same, and the metal impedance plate, for example, in the shape of a rectangle. 41. The antenna according to claim 35, characterized in that the width of the metal impedance plate in the direction of the longitudinal axis of symmetry of the segment of the symmetrical slot line from the maximum to the region of the minimum aperture of the antenna aperture is made to increase or decrease, and the increase or decrease in the width of the metal impedance plate is described as linear or nonlinear function. 42. The antenna according to paragraph 41, wherein the non-linear function has the form: y = ax ^{± m / n} , where a is the coefficient, is given by a real number;
m, n are positive integer coprime numbers, with n>m;
x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line. 43. The antenna according to paragraph 41, wherein the non-linear function has the form: y = ae ^bx + ce ^dx , where a, b, c, d are coefficients, are given by real numbers;
x is the coordinate corresponding to the longitudinal axis of symmetry of a segment of a symmetrical slot line.

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