WO2011059364A1 - Planar antenna - Google Patents

Abstract

The invention relates to the field of radio technology, more specifically to ultra-wideband printed antennae in the SHF range, and can be used in communication systems, radiographic inspection, radio monitoring, and in other systems. The technical result of the invention is the production of a broadband planar antenna that is capable of simultaneously radiating and receiving both longitudinal electromagnetic waves and transverse electromagnetic waves via a single aperture and separate, non-overlapping channels, and that demonstrates a low level of variation in matching behaviour and has a simple and high-tech design. The planar antenna comprises a printed symmetrical slotline formed by two identical metal plates which are coupled by a metal connecting strip on one side and are situated on the same plane of a dielectric substrate, on the other surface of which is a section of a signal stripline. The antenna aperture is formed by a section of the expanding printed symmetrical slotline, which section is a continuation of a section of a printed uniform symmetrical slotline of the conductor.

Description

 Planar antenna

FIELD OF THE INVENTION

 The invention relates to the field of radio engineering, in particular, to ultra-wide-band printed antennas of a microwave frequency range, and can find application in communication systems, in radio defectoscopy, in tasks of radio monitoring, in tasks of electromagnetic compatibility (EMC) of radio engineering systems, as part of phased antenna arrays, in metrology, in medicine for electromagnetic applicators and hyperthermia problems.

State of the art

A broadband antenna is known (Patent RU 2298268, IPC Н 01Q 9/00, published on April 27, 2007), made on the basis of a printed anti-fake slotted line (ASCHL). The aperture of the antenna is formed by a segment of the APSHL without overlapping and contains two identical metal plates located on different sides of the dielectric substrate, one of which is signal and the other is earthen. In the radiating part of the antenna, the metal plates of the ASCI are made exponentially expanding along the inner side edge from the region of zero overlap of the ASCI to the region of maximum aperture opening, while in the aperture of the antenna along the inner side edge of the signal and ground metal plates from the region of zero overlap to the region of maximum With a small aperture of the antenna aperture, metallic radiating surfaces are installed perpendicular to the plane of the dielectric substrate. The signal conductor of the asymmetric strip line segment is end-face galvanically connected to the inner lateral edge of the APCHL signal metal plate in the region of zero overlap, and its earth plane is placed with the earth metal plate on the same surface of the dielectric substrate in the region of zero APCHL cover and is galvanically connected to the end side edge of the earthen metal plate.

 A disadvantage of the known technical solution is the impossibility, along with the emission and reception of transverse electromagnetic waves, to form a mode of emission and reception of longitudinal electromagnetic waves.

The closest technical solution to the prototype is a transceiver planar antenna of transverse electromagnetic waves (Patent DE 3941125, MP N 01 Q 13/10, publ. 06/20/1991), containing two identical dielectric substrates, installed one on the other , and two identical, shorted at one end, segments of a symmetrical slotted line (SHL) located on the outer surface of one and the other dielectric substrates, respectively, while on the alignment surface between one and the other dielectric substrates from The signal line striker, for which the ground surfaces are the metal plates of two segments of a homogeneous symmetrical slit line (OSCHL), thereby forming a segment of a symmetrical shielded strip line, with one end of the signal strip conductor intersecting a segment of one and the other SSL at a right angle, and the other end is connected to the sewer 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 of the antenna aperture, and the identical metal plates forming it are made narrowing along the inner lateral edge from the area of the beginning of expansion of AHB to the area of maximum aperture of the antenna aperture, at In this case, the longitudinal axis of symmetry of the segment of the SLR and the longitudinal axis of symmetry of the segment of the expanding SLL lie on one axis that is parallel to the longitudinal axis of the antenna located on top combination of one and another dielectric substrate, while the axis of symmetry of the segments OSL and AL and the axis of symmetry of the antenna are located in the same plane perpendicular to the dielectric substrates.

 The disadvantages of the known technical solution are the inability to form a mode of emission and reception of longitudinal electromagnetic waves, and simultaneously simultaneously emit and receive separately and longitudinally, transverse electromagnetic waves separately through channels decoupled by one aperture.

SUMMARY OF THE INVENTION

 The main technical task of this invention is to create a broadband planar antenna capable of simultaneously emitting and receiving longitudinal electromagnetic waves and transverse electromagnetic waves with a single aperture along separate, decoupled channels, with a low level of uneven matching characteristics, simple and high-tech design.

The indicated technical problem is solved by a planar antenna containing a printed symmetrical slotted line formed by two identical metal plates, which are interconnected by a metal bridge on one side and placed on one surface of the dielectric substrate, on the other surface of which a segment of the signal strip is located lines, the aperture of the antenna is formed by a segment of an expanding printed symmetrical slotted line, which is a continuation of a segment of a printed homogeneous symmetry egg slit line, and the identical metal plates forming it are made tapering along the inner lateral edge from the region of the beginning of expansion of the printed symmetrical slit line to the region of maximum aperture of the antenna aperture, while on one side a segment of the signal strip line intersects the segment of the printed one - a uniform symmetrical slot line at a right angle, and on the other On the side of the signal strip line segment is connected to the channel transmission line, while the ground surface of the signal strip line section is one of the metal plates of the printed homogeneous symmetrical slotted line section.

 The novelty of the proposed planar antenna lies in the fact that an additional dielectric substrate is identical to the dielectric substrate, which is installed on one side of the printed symmetrical slotted line with one surface on the surface of the dielectric substrate and completely covers it, and on the other surface, which is placed the introduced segment of the additional signal stripe line, the earth surface of which is one and the other metal plates of the segment of the printed homogeneous symmetric the slit line, and the longitudinal axis of symmetry of the segment of the additional signal strip line is parallel to the longitudinal axis of symmetry of the segment of the printed homogeneous symmetrical slot line and is located with it in the same plane perpendicular to the dielectric substrate, and the segment of the additional signal strip line, located on one side in the area of the aperture of the antenna is connected to the exciting element, made in the form of a segment of an axisymmetric strip conductor, and on the other hand, the segment is additionally signal stripline disposed by a metal jumper connected to channeling additional transmission line, wherein the longitudinal axis of symmetry of the exciting member is aligned with the longitudinal axis of symmetry of the segment signal further stripline.

A planar antenna allows a single aperture to receive and emit electromagnetic waves of two different electrodynamic and physical properties through separate channels, separated from each other: transverse electromagnetic waves along one channel; on another channel - longitudinal electromagnetic waves. Decoupling of segments of the signal and additional signal strip lines, i.e. one of the other channels is ensured by the fact that the signal strip line segment — for the transverse electromagnetic wave and the additional signal strip line segment — for the longitudinal electromagnetic wave, are mutually orthogonal in the intersection region and the signal strip lines are located on opposite sides of the aperture on the surfaces of the dielectric and additional dielectric substrates, respectively.

 A planar antenna can be implemented with the introduction of the second and third additional dielectric substrates identical to the dielectric substrate, the second additional dielectric substrate with one surface mounted on the surface of the dielectric substrate from the location of the segment of the signal strip line and completely covers it, and the third an additional dielectric substrate with one surface is mounted on the surface of the first additional dielectric substrate from the location side o cutting of an additional signal stripline, and it completely closes.

 A planar antenna can be implemented with the introduction of the first and second additional print SLR identical to the print SLR, with the first additional print SLL installed on the other surface of the second additional dielectric substrate, and the second additional print SLR installed on the other surface of the third additional dielectric substrate moreover, the first and second additional printed SHL are located symmetrically relative to the plane of the printed SHL, the metal bridge of which is galvanized - canonically connected to the metal jumper first m of additional second printed symmetric slot lines.

Planar antenna can be made with the fourth and fifth additional real dielectric substrates, which are identical to the dielectric substrate, each of which is installed on one surface on the surface of the first and second additional printed SLBs with one surface, respectively, and completely covers them.

 A planar antenna can be made with a width of dielectric substrates equal to the width of the maximum aperture of the antenna aperture.

 A planar antenna can be made with a width of dielectric substrates greater than the width of the maximum aperture of the antenna aperture.

 A planar antenna can be implemented with the introduction of the aperture segment of the print OSL, the width of which is equal to the width of the expanding print SBL in the region of the maximum aperture of the antenna aperture, while the inner side edges of the aperture segment of the print OSL are parallel to the axis of symmetry of the print SHL, and the aperture segment of the print OSL is galvanically connected to the print ASC in the area of maximum aperture opening.

 At least one director can be installed in the region of the aperture segment of the print OSL, made in the form of a strip conductor and located symmetrically with respect to the internal lateral edges of the aperture segment of the print OSL and perpendicular to its longitudinal axis.

 The metal plates that form the printed SHL in the region of the aperture of the antenna can be narrowed along the inner lateral edge along the longitudinal axis of symmetry in the direction from the region of the joint with the segment of the printed SHL to the region of maximum aperture opening, and the law of narrowing can be described linear or a non-linear function, or may alternate between linear and non-linear segments described by linear and non-linear functions, respectively.

The outer lateral edges of the metal plates may be parallel are integral with the longitudinal axis of symmetry of the antenna.

 The outer lateral edges of the metal plates in the direction from the region of the maximum to the region of the minimum aperture of the antenna aperture along its longitudinal axis of symmetry along the entire length can be tapering or expanding, and the law of change is described by a linear or nonlinear function.

 The strip conductor of the exciting element can be made in the form of a rectangular plate.

 The strip conductor of the exciting element can be made in the form of an expanding plate along two external lateral edges along the longitudinal axis of symmetry, in the direction from the region of the minimum to the region of maximum aperture opening, and the law of expansion is described by a linear or nonlinear function.

 An adapter can be connected coaxially between the length of the additional signal strip line and the strip conductor of the drive element.

 The transition device can be performed:

 - in the form of an axisymmetric strip conductor;

 - in the form of a gap between the end face of a segment of an additional signal strip line and the end face of the strip conductor of the exciting element;

- in the form of a semiconductor element with an adjustable electric capacitance included in the gap between the end face of a segment of an additional signal strip line and the end face of the strip conductor of the exciting element.

At one and the other side edges, extended along the longitudinal axis of the strip conductor of the exciting element, can be installed, at least one pair of identical strip matching elements, respectively, one on one and the other outer side edge, while strip matching elements are located symmetrically with respect to the longitudinal axis of the segment of the additional signal strip line.

 The strip matching element may be made of at least one impedance loop in the form of a ribbon conductor, which is galvanically connected to the outer lateral edge of the strip conductor of the exciting element.

 The strip matching element can be made of at least one non-uniform impedance loop, which can be connected to the outer side edge of the strip conductor of the exciting element galvanically or electromagnetically. Electromagnetic coupling, for example, may be in the form of a uniform gap or in the form of a non-uniform gap.

 At least one strip matching element, which is located symmetrically with respect to the longitudinal axis of the section of the additional signal strip line, is installed on the end lateral edge opposite to the edge of the connection of the exciting element to the segment of the additional signal strip line. It is galvanically or electromagnetically switched in the form of a gap.

 On the one hand, a galvanic impedance load can be connected to a segment of the signal strip line, which is made in the form of a strip region and can be in the form of a circle or sector.

Two identical axisymmetric metal impedance plates can be installed on the side of one and the other lateral edges of the metal plates of the printed symmetrical slit line, while the impedance metal plates are located symmetrically with respect to the plane of the metal plates of the printed symmetrical slit line and perpendicularly this plane, and each metal impedance plate is galvanically connected by the contact element with the corresponding external the edge of the metal plate of a printed symmetrical slit line.

 When performing an antenna with three printed SSCLs, the metal plates forming them are connected by external lateral edges to the corresponding metal impedance plate through the contact element identical to the connection of metal plates of one printed SSCL.

 The contact element can be made:

 - in the form of a metal rod, the installation location of which is determined by the portion of the outer lateral edge of the metal plate of the printed SSCL corresponding to the antenna aperture;

 - in the form of a tape conductor, which is installed along the outer lateral edge of the metal plate of the printed SSCL and is located with it in the same plane;

 - in the form of a semiconductor element with an adjustable electrical capacitance, the installation location of which is determined by the portion of the outer lateral edge of the metal plate of the printed SSCL corresponding to the antenna aperture;

 - in the form of an inductance coil in printed or volumetric design, which is installed along the outer lateral edge of the metal plates of the printed SSCL.

 The metal impedance plate along the longitudinal axis of the antenna can be made of constant width, for example, in the shape of a rectangle.

 The metal impedance plate along the longitudinal axis can be made of increasing or decreasing width, and the law of variation of the width along the outer lateral edge is described by a linear or nonlinear function.

A nonlinear function may look like: RU2010 / 000607

 10

Y = ax ^{± t / n} ,

where: a - coefficient, is given by a real number;

m, n are positive integer coprime numbers, and n> w;

x is the coordinate corresponding to the longitudinal axis of the antenna;

or may 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 the antenna.

 Brief Description of the Drawings

In FIG. 1 - shows the design of a planar antenna with two dielectric substrates; in FIG. 2 - planar antenna with two additional dielectric substrates and with two additional printed SLRs; in FIG. 3 is a cross section of a planar antenna with two dielectric substrates (Fig. 1) in the region of segments of the signal and additional signal strip lines; in FIG. 4 is a cross-sectional view of a planar antenna with two external third and fourth additional dielectric substrates (Fig. 1) in the region of segments of the signal and additional signal strip lines; in FIG. 5 is a cross-sectional view of a planar antenna with two external second and third additional printed SLBs (Fig. 2) in the region of signal and additional signal strip segments; in FIG. 6 is a cross-sectional view of a planar antenna with two external fourth and fifth additional dielectric substrates in the region of segments of the signal and additional signal strip lines; in FIG. 7 - shows a longitudinal section of a planar antenna (Fig. 1) with a width of dielectric substrates equal to the width of the maximum aperture of the aperture of the antenna and with a linear narrowing of the metal plates of the printed SCHL along the inner side edge in the region of the aperture 0607

 eleven

ry; in FIG. 8 - shows a longitudinal section of a planar antenna (Fig. 1) with a width of dielectric substrates greater than the width of the maximum aperture of the antenna aperture in the area of the printed SLR; in FIG. 9 - shows a longitudinal section of a planar antenna (Fig. 1) with an aperture section of a printed OSPL; in FIG. 10 - shows a longitudinal section of a planar antenna (Fig. 1), in which one director is installed in the area of the aperture segment of the printed OSSCL, made in the form of a rectangular strip conductor; in FIG. 11 and Fig. 12 shows a longitudinal section of a planar antenna (Fig. 1), the metal plates of the printed SLB of which are convex and concave in the area of the antenna aperture along the inner lateral edge, respectively; in FIG. 13, in FIG. 14 and in FIG. 15 shows a longitudinal section of a planar antenna (Fig. 1), the metal plates of the printed ASC of which linearly, nonlinearly convexly and nonlinearly bend along the outer lateral edges along the longitudinal axis of symmetry in the direction from the region of maximum to the region of minimum aperture opening; in FIG. 16, in FIG. 17 and in FIG. 18 shows a longitudinal section of a planar antenna (Fig. 1), the metal plates of the printed AHB which linearly, nonlinearly convexly and nonlinearly extend along the outer lateral edges along the longitudinal axis of symmetry in the direction from the region of maximum to the region of minimum aperture opening; in FIG. 19 is a strip conductor of an exciting element in the shape of a rectangle; in FIG. 20, in FIG. 21 and in FIG. 22 - strip conductor of the exciting element, expanding linearly, nonlinearly concave and nonlinearly convex, respectively, along two external lateral edges; in FIG. 23, in FIG. 24 and in FIG. 25 is a transition device between a section of an additional signal strip line and a strip conductor of the exciting element in the form of an axisymmetric ribbon conductor, in the form of an air gap and in the form of a semiconductor cop, respectively; in FIG. 26, in FIG. 27 and in FIG. 28 is a strip matching element in the form of three pairwise identical impedance loops in the form of a ribbon conductor, in the form of one pair of identical inhomogeneous impedance loops made in the form of a triangular strip conductor, and in the form of two pairs of pairwise identical inhomogeneous impedance loops in the form of a triangular strip conductor, respectively, which are galvanically connected to the external lateral edges of the strip conductor of the exciting element; in FIG. 29 - strip matching element in the form of a heterogeneous impedance loop in the form of an isosceles triangular strip conductor, which is galvanically connected to the end lateral edge of the strip conductor of the exciting element; in FIG. 30 and in FIG. 31 - a strip matching element in the form of one pair of identical inhomogeneous impedance loops, which are connected by a homogeneous and inhomogeneous, respectively, electromagnetic coupling with the outer lateral edges of the strip conductor of the exciting element; in FIG. 32 and in FIG. 33 is a longitudinal section of a planar antenna (FIG. 1), in which a galvanic impedance load in the form of a strip region in the form of a sector and in the form of a circle, respectively, is connected to the end of a segment of a signal strip conductor in the area of the printed OSL; in FIG. 34 and in FIG. 35 is a longitudinal section of a planar antenna (Fig. 1) with a galvanic connection of metal impedance plates to metal plates of a printed circuit board with contact elements made in the form of a rod and in the form of a ribbon conductor, respectively; in FIG. 36, in FIG. 37, in FIG. 38 and in FIG. 39 - planar antenna with metal impedance plates, constant width, linearly decreasing width, decreasing width of the convex shape, and decreasing width of the concave shape, respectively, from the region of maximum to the region of minimum aperture opening; in FIG. 40, in FIG. 41 and in FIG. 42 is a planar antenna with metal impedance plates, of constant width, linearly increasing width, increasing convex-shape width, and increasing concave-shaped width, respectively, from the region of maximum to the region of minimum aperture opening.

 Detailed description of preferred embodiments.

 The planar antenna (Fig. 1) contains a printed SSL 1 formed by two identical metal plates 2, which are interconnected on one side by a metal jumper 3 and placed on one surface of the dielectric substrate 4, on the other surface of which there is a segment of the signal strip line 5 moreover, the antenna aperture is formed by a segment of an expanding printed SSCL 6, which is a continuation of a segment of a printed SSCL 7, and the identical metal plates 2 forming it are made narrowing along the inside therein the side edge 8 of the minimum area to the region of the maximum aperture of the aperture antenna. An additional dielectric substrate 9, which is identical to the dielectric substrate 4, is mounted on one surface on the surface of the dielectric substrate 4 from the side of the printed SLB 6 and completely covers it, and on the other surface there is a segment of an additional signal strip line 10 connected on one side to the exciting element 11.

The second additional dielectric substrate 12 (Fig. 2) is mounted on the surface of the dielectric substrate 4 from the location of the segment of the signal strip line 5, and the third additional dielectric substrate 13 with one surface is mounted on the surface of the first additional dielectric substrate 9 from the location side of a segment of an additional signal strip line 10. The first and second, additional printed СШЛ 14 and 15 are installed on the second and third additional dielectric substrates 12 and 13, respectively respectively (Fig. 2, Fig. 5).

 The fourth and fifth additional dielectric substrates 16 and 17 cover the first and second additional printed SLR 14 and 15 (Fig. 6).

 A planar antenna in the plane of the location of the printed SSCL 1 (Fig. 9) is made with an aperture segment 18 of the printed SSCL. Director 19 (Fig. 10) in the form of a strip conductor is installed in the region of the aperture segment 18 of the printed OSL.

 The outer lateral edges 20 of the metal plates 2 of the printed slab have various shapes (Figs. 13-18).

 The outer lateral edges 21 of the strip conductor of the exciting element 11 have various shapes (Fig. 19 - Fig. 22).

 Between the end face of the segment of the additional signal strip line 10 and the end face of the strip conductor of the exciting element, an adapter 22 of various designs is included (Fig. 23 - Fig. 25). On each external lateral edge 21 of the strip conductor of the exciting element 11, strip matching elements 23 are galvanically mounted in the form of various types of impedance loops (Fig. 26 - Fig. 28), in the form of an isosceles triangle connected galvanically to the end side edge 24 of the strip conductor of the drive element 11 (FIG. 29).

 The strip matching element 23 is electromagnetically connected to the strip conductor of the exciting element 11 in the form of a uniform gap 25 and a non-uniform gap 26, respectively (Fig. 30, Fig. 31).

 The impedance load 27 is made of various shapes (Fig. 32 and Fig. 33).

In a planar antenna, metal impedance plates 28 are galvanically connected by contact elements 29 to metal plates 2 in the region of the maximum aperture opening (Fig. 35, Fig. 36). T RU2010 / 000607

fifteen

 A planar antenna operates as follows.

 We consider the operation of a planar antenna separately for each channel, i.e. along the channel of transverse electromagnetic waves and along the channel of longitudinal electromagnetic waves. In the mode of reception and emission of transverse electromagnetic waves, a planar antenna (Fig. 1) operates as follows.

 An input microwave signal of a wave of type T is fed to a segment of the signal strip line 5 located above the metal plate 2, a cut of the printed OSL 7 and separated by a dielectric substrate 4, i.e. to the segment of the asymmetric strip line of the T wave. The region of the orthogonal intersection of the segment of the signal strip line 5 and the segment of the printed REFL 7, separated by the dielectric substrate 4, is a mode-impedance transformer matched by wave impedance, where the type T wave is asymmetric strip line is transformed into a wave of the type NU printed OSCHL (Gvozdev V.I., Nefedov E.I. / Volumetric integrated circuits microwave // // M .: Nauka. Main edition of the physics and mathematics literature // 1985. - 256 p. silt). The NU-type excited wave in the segment of the printed OSL 7 is a transverse electromagnetic wave with a flat front, it is transformed in the segment of the expanding printed SSL 6, i.e. in the aperture of the antenna, into a transverse electromagnetic wave of the NU type, which has a spherical front, which radiates into free space. (Benoit Stockbroeckx, Andre Vander Vorst / Copolar and Cross-Polar Radiation of Vivaldi Antenna on Dielectric Substrate. // NEX Trans / on Antenna and Propag. // V.48, No.l, January 2000, pp.19-25) .

 Similarly, a planar antenna operates in receive mode.

In the mode of reception and emission of longitudinal electromagnetic waves, a planar antenna operates as follows. The input microwave signal of a wave of type T is fed to a segment of an additional signal strip line 10, separated by an additional dielectric substrate 9 from a segment of planar OSL 7, and located symmetrically with respect to the metal plates 2 that form it, which, in turn, for a segment of additional the signal strip line 10 are earthen plates, i.e. on a segment of a coplanar strip line of a wave of type T. (Sachse K., Sowicki A. // New microstrip transmission lines for microwave integrated circuits. // In: IEEE Proc. Microwave Symp.// 1979, p. 468 - 470. ) An exciting element 11 is coaxially connected to a segment of an additional signal strip line 10 in the region of the antenna aperture, that is, in the area of the expanding printed SLB 6, metal plates 2 forming a segment of the printed SLR 7 and a segment of the expanding printed SLR 6, interconnected by a metal jumper 3, are under the same potential and at the same time perform the function of earthlings of the wafers with respect to the cut of the additional signal strip line 10 and the aperture of the antenna, and the segment of the additional signal strip line 10 is at a different potential. The aperture region of the antenna with the exciting element 11 having the same potential as the length of the additional signal strip line 10 can be considered as two identical inhomogeneous transmission lines of a transverse electromagnetic wave of type T with a common central conductor, namely : the common conductor is a segment of an additional signal strip line 10, and the other two conductors are one and the other metal plates 2 of the printed SCL 1. The exciting element 11 on the surfaces of one and the other metal plates 2 excites I surface conduction currents corresponding transverse electromagnetic waves excite T. type conductivity surface current RU2010 / 000607

 17

of the bridge on the surface of each metal plate 2 in the region of the aperture of the antenna generates an electric field vector E, which is characterized by two components of the electric field Eo and E -'- relative to the longitudinal axis of symmetry of the antenna. The first of them, Eo, is parallel to the longitudinal axis of symmetry of the antenna, and the second E -> - is orthogonal to the axis of symmetry of the antenna. Due to the symmetry of the antenna, with respect to the coordinate plane passing through the middle of the dielectric substrates 4 and 9, and perpendicular to them, the components of the electric field E0 are oriented identically and, accordingly, are summed in the aperture, and the components of the electric field E - * are oriented opposite and respectively mutually compensated in the aperture. As a result of the summation of all the components of the electric field Eo on the metal plates 2 of the printed SSHL 1, a longitudinal electromagnetic wave is generated and emitted in the aperture. Thus, the primary transverse electromagnetic wave is transformed into a secondary longitudinal electromagnetic wave radiated into free space.

 The orthogonal intersection of the segment of the signal strip line 5 and the segment of the additional signal strip line 10, separated by the dielectric and additional dielectric substrates 4 and 9, respectively, provides a high level of isolation between them.

Thus, a planar antenna (Fig. 1) per one aperture can receive and emit, along separate decoupled channels, longitudinal and transverse electromagnetic waves.

 The use of additional second 12 and third 13 dielectric substrates (Fig. 2, Fig. 4) in a planar antenna allows one to reduce radiation losses of signal 5 and additional signal 10 segments of strip lines.

A planar antenna with additional first and second printed AWLs 14 and 15 (FIG. 2, FIG. 5) allows receiving on separate apertures and emit transverse and longitudinal electromagnetic waves.

 The use of additional fourth 16 and fifth 17 dielectric substrates (Fig. 6) provides uniform dielectric filling for a planar antenna.

 Thus, optimally choosing the structure of the planar antenna (Fig. 1 - Fig. 6), the dimensions of the dielectric substrate 4 (Fig. 7 and Fig. 8), the use of aperture segment 18 (Fig. 9), director 19 (Fig. 10), the shape of the metal plates 2 along the inner side edge 8 (Fig. 11 and Fig. 12), the shape of the metal plates 2 along the outer side edge 20 (Fig. 13 - Fig. 18), the shape of the plates of the driving elements 1 1 (Fig. 19 - Fig. 22), view of the adapter 22 (Fig. 23 - Fig. 25), view of the matching device 23 and the method of its connection (Fig. 26 - Fig. 31), view of the impedance the load 27 (Fig. 32, Fig. 33), the options for connecting the contact elements 29 of the metal impedance plates 28 to the metal plates 2 of the printed SCL 1 (Fig. 34 and Fig. 35), the shape of the metal impedance plates 28 (Fig. 36 - Fig. 42), we realize the design of the planar antenna for the given electrical characteristics.

Claims

Claim

1. A planar antenna containing a printed symmetrical slit line formed by two identical metal plates that are interconnected by a metal jumper on one side and placed on one surface of the dielectric substrate, on the other surface of which there is a segment of the signal strip line, the antenna aperture is formed by a segment of an expanding printed symmetric slit line, which is a continuation of a segment of a printed homogeneous symmetrical slit line, and its generators are the same th metal plates are made tapering along the inner lateral edge from the region of the beginning of expansion of the printed symmetrical slotted line to the region of maximum aperture of the antenna aperture, while on one side a segment of the signal strip line intersects the segment of the printed homogeneous symmetrical slotted line at right angles, and on the other hand, a segment of the signal the strip line is connected to the sewer transmission line, while the ground surface of the signal strip segment is one of the metallic of their plates of a segment of a printed homogeneous symmetrical slit line, characterized in that an additional dielectric substrate is introduced, identical to a dielectric substrate, which is installed on one side of the surface of the printed symmetrical slot line with one surface on the surface of the dielectric substrate and completely covers it, and on the other surface of which the introduced segment is placed additional signal strip line, the earth surface of which is one and the other metal plates of the furnace homogeneous symmetric slotted line, and the longitudinal axis of symmetry of the segment of the additional signal strip line parallel to the longitudinal

SUBSTITUTE SHEET (RULE 26) the axis of symmetry of a segment of a printed homogeneous symmetric slit line and is located with it in the same plane perpendicular to the dielectric substrate, and a segment of an additional signal strip line, located on the one hand in the region of the aperture of the antenna, is connected to an exciting element made in the form of a segment of an axisymmetric strip conductor, and on the other hand, a segment of an additional signal strip line located on the side of the metal bridge is connected to an additional channel a transmission line, wherein the longitudinal axis of symmetry of the exciting member is aligned with the longitudinal axis of symmetry of the segment signal further stripline.

 2. The planar antenna according to claim 1, characterized in that the second and third additional dielectric substrates are introduced, identical to the dielectric substrate, the second additional dielectric substrate with one surface mounted on the surface of the dielectric substrate from the location of the segment of the signal strip line and completely covers it, and the third additional dielectric substrate with one surface mounted on the surface of the first additional dielectric substrate from the location of the negative Cutting an additional signal strip line and completely closes it.

 3. The planar antenna according to claim 2, characterized in that the first and second additional printed symmetric slit lines are identical to the printed symmetrical slit line, while the first additional printed symmetrical slit line is installed on the other surface of the second additional dielectric substrate, and the second additional printed a symmetrical slit line is installed on another surface of the third additional dielectric substrate, with the first and second additional

SUBSTITUTE SHEET (RULE 26) chat symmetrical slotted lines are located symmetrically relative to the plane of the printed symmetrical slotted line, the metal bridge of which is galvanically connected to the metal bridge of the first and second additional printed symmetrical slotted lines.

 4. The planar antenna according to claim 3, characterized in that the fourth and fifth additional dielectric substrates are introduced that are identical to the dielectric substrate, each of which is mounted on one surface of the first and second additional printed symmetrical slit line, respectively, and completely covers them.

5. The planar antenna according to claim 1, characterized in that the width of the dielectric substrates is equal to the width of the maximum aperture of the antenna aperture.

 6. The planar antenna according to claim 1, characterized in that the width of the dielectric substrates is greater than the width of the maximum aperture of the antenna aperture.

 7. The planar antenna according to claim 1, characterized in that an aperture segment of a printed homogeneous symmetrical slotted line is introduced, the width of which is equal to the width of an expanding printed symmetrical slotted line in the region of maximum aperture opening, while the inner side edges of the aperture segment of a printed homogeneous symmetrical slotted line are parallel the axis of symmetry of the printed symmetrical slotted line, and the aperture segment of the printed homogeneous symmetrical slotted line is galvanically connected to the printed symmetrical shield Eve line in the region of maximum aperture of the aperture.

 8. The planar antenna according to claim 7, characterized in that at least at least one director is introduced in the region of the aperture segment of the printed homogeneous symmetrical slit line.

SUBSTITUTE SHEET (RULE 26) gloss conductor, located symmetrically relative to the inner side edges of the aperture segment of the printed homogeneous symmetrical slot line and perpendicular to its longitudinal axis.

9. The planar antenna according to claim 1, characterized in that the narrowing of the metal plates of the printed symmetrical slotted line in the aperture along the inner lateral edge along the longitudinal axis of symmetry in the direction from the region of the connection with the printed homogeneous symmetrical slotted line to the region of maximum aperture opening is described as linear or a non-linear function, or may alternate between linear and non-linear or non-linear and linear segments described by linear or non-linear functions, respectively.

 10. A planar antenna according to claim 1, characterized in that the metal plates along the outer lateral edge are made parallel with respect to its longitudinal axis of symmetry.

 1 1. The planar antenna according to claim 1, characterized in that the metal plates along the outer lateral edge along its longitudinal axis of symmetry in the direction from the region of the maximum aperture to the region of the minimum aperture are made identically tapering or expanding, wherein the narrowing or expansion of the metal plates described by a linear or non-linear function.

 12. The planar antenna according to claim 1, characterized in that the strip conductor of the exciting element is made in the form of a rectangular plate.

 13. The planar antenna according to claim 1, characterized in that the strip conductor of the exciting element is made in the form of a plate expanding along two external lateral edges along the longitudinal axis of symmetry in the direction from the region of the connection with the segment of the additional signal strip line to the region of maximum

SUBSTITUTE SHEET (RULE 26) aperture opening, while the law of expansion is described by a linear or nonlinear function.

 14. The planar antenna according to claim 1, characterized in that between the segment of the additional signal strip line and the strip conductor of the exciting element, an adapter is coaxially connected.

 15. The planar antenna according to claim 14, characterized in that the transition device is made in the form of an axisymmetric strip conductor.

16. The planar antenna according to claim 14, characterized in that the transition device is made in the form of a gap between the end face of a segment of an additional signal strip line and the end face of the strip conductor of the exciting element.

 17. The planar antenna according to claim 16, characterized in that a semiconductor element with an electrically adjustable capacitance is included in the gap.

 18. A planar antenna according to claim 1, characterized in that at least one pair of identical strip matching elements is installed on one and the other side edges extended along the longitudinal axis of symmetry of the strip conductor of the exciting element, respectively, while the strip matching the elements are located symmetrically relative to the longitudinal axis of the segment of the additional signal strip line.

 19. The planar antenna according to claim 18, characterized in that the strip 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 strip conductor of the exciting element.

 20. The planar antenna according to claim 18, characterized in that the strip matching element is made in the form of at least one inhomogeneous impedance loop.

SUBSTITUTE SHEET (RULE 26)

21. The planar antenna according to claim 20, characterized in that the inhomogeneous impedance loop is connected galvanically to the outer side edge of the strip conductor of the exciting element.

 22. The planar antenna according to claim 20, characterized in that the inhomogeneous impedance loop is connected electromagnetically to the outer lateral edge of the strip conductor of the exciting element.

 23. A planar antenna according to claim 22, characterized in that the electromagnetic coupling is made in the form of a uniform or inhomogeneous gap.

 24. The planar antenna according to claim 1, characterized in that at least one strip matching element that is located symmetrically with respect to the longitudinal axis of the additional segment is installed on the end lateral edge opposite to the edge of the connection of the exciting element to the length of the additional signal strip line the signal strip line, while the strip conductor of the matching element is connected to the strip conductor of the exciting element galvanically or electromagnetically in the form of a gap.

 25. The planar antenna according to claim 1, characterized in that, on the one hand, an impedance load made in the form of a strip conductor is galvanically connected to a segment of the signal strip line.

 26. A planar antenna according to claim 25, characterized in that the strip conductor of the impedance load is made in the form of a circle or sector.

 27. The planar antenna according to claim 1, characterized in that two identical axisymmetric metal impedance plates are introduced, which are mounted on the side of one and the other outer side edges of the metal plates of a printed symmetrical slot line, while the impedance metal plates are symmetrically relative to the plane of the metal plates printed symmetrical slit line and perpendicular to this plane, and

SUBSTITUTE SHEET (RULE 26) each metal impedance plate is galvanically connected by a contact element to a corresponding external lateral edge of a metal plate of a printed symmetrical slotted line.

 28. A planar antenna according to claim 3, characterized in that two identical axisymmetric metal impedance plates are introduced, which are mounted on the side of one and the other outer lateral edges of the metal plates of a printed symmetrical slot line, while the impedance metal plates are located symmetrically relative to the plane of the metal plates printed symmetrical slit line and perpendicular to this plane, with each metal impedance plate galvanically connected contact element with corresponding outer side edge of the metal plate printed symmetric slot line and the first and second additional printed circuit symmetrical slotline.

 29. The planar antenna according to claim 28, 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 opening.

 30. The planar antenna according to claim 28, characterized in that the contact element is made in the form of a metal rod that is mounted on a segment of the outer lateral edge of the metal plates of an expanding printed symmetrical slotted line.

 31. The planar antenna according to claim 28, characterized in that the contact element is made in the form of a ribbon conductor, which is installed along the outer side edge of the metal plates of an expanding printed symmetrical slot line from the region of maximum aperture opening to the area of minimum aperture opening.

 32. The planar antenna according to claim 28, characterized in that the contact element is made in the form of a semiconductor element with an electrically adjustable capacitance that is mounted on an external segment

SUBSTITUTE SHEET (RULE 26) the lateral edge of the metal plates of an expanding printed symmetrical slit line.

 33. The planar antenna according to claim 28, characterized in that the contact element is made in the form of an inductance coil in volumetric or printed design, which is installed along the outer side edge of the metal plates of an expanding printed symmetrical slot line from the region of maximum aperture opening to the region of minimum aperture opening.

 34. The planar antenna according to claim 28, characterized in that the width of the metal impedance plate from the region of the maximum aperture to the region of the minimum aperture is the same.

 35. The planar antenna according to claim 28, characterized in that the width of the metal impedance plate from the region of maximum aperture to the region of minimum aperture is made to increase or decrease, and increasing or decreasing the width of the metal impedance plate is described by a linear or non-linear function.

 36. Planar antenna according to p. 9, or 1 1, or 13, or 35, characterized in that the non-linear function has the form

where: a - coefficient, is set by a real number;

 m, n are positive integer coprime numbers, with n> m; x is the coordinate corresponding to the longitudinal axis of the antenna.

37. Planar antenna according to p. 9, or 1 1, or 13, or 35, characterized in that the non-linear function has the form

SUBSTITUTE SHEET (RULE 26) y = ae ^bx + ce ^dx ,

where: a, b, c, d - coefficients, are given by real numbers; x is the coordinate corresponding to the longitudinal axis of the antenna.

SUBSTITUTE SHEET (RULE 26)