RU2156524C2 - Microstrip antenna array - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: microwave antenna array can be used in radiointroscopes to measure parameters of Muller matrix for flaw detection in construction engineering and in electromagnetic microwave medical applicators. Antenna array has single aperture accommodating two sub-arrays; one of them is transmitting sub-array that functions to radiate linearly or horizontally polarized signal, or circularly polarized signal with polarization vector rotating clockwise or counter-clockwise; other one is receiving sub-array ensuring decomposition of wave received into two orthogonally polarized components and their discrimination in separate channels. Antenna has even number of radiators forming rectangle and located in assemblies of rectangular coordinate grid where they are spaced apart by gaps. Central radiators of four beams of rectangular coordinate grid are rectangular in shape whose one side equals wavelength and its adjacent side is as long as half-wavelength. Remaining radiators are square in shape with square side as long as wavelength. Four central radiators closest to origin of antenna array coordinates are electrically connected over center line to ground surface of array through contact members. Connected to each central radiator at point located in center of side edge is section of input transmission line and each central radiator is connected to respective antenna feed. EFFECT: enlarged functional capabilities. 8 cl, 8 dwg

Description

 The invention relates to the field of radio engineering, in particular to flat microstrip microwave arrays, and can find application in radio introscopes using microwave waves to measure the parameters of a matrix for defectoscopy in construction, in medical diagnostic microwave electromagnetic applicators.

 Known Microstrip Antenna (Daniel H. Schaubert, Frederick G. Farrar, Arthur Sindoris, Scott T. Hayes / Microstrip Antennas with Frequency Agility and Polarization Diversity, IEEE Transactions on Antennas and Propagation, vol. AP-29, 1981, N 1, January , pp. 118-123), containing a square-shaped emitter, to which four independent coaxial inputs are connected to form four different types of polarization: linear - vertical and horizontal, circular - right-handed and left-handed. The type of polarization is established by switching the corresponding input of the emitter to the microwave energy source. In the formation of polarized-controlled transceiver antenna arrays on the basis of such emitters, rather complex (branching) feeder circuits with a large number of power dividers and switching devices are required, which leads to significant losses of microwave power, high power of a DC voltage source for switching devices, a complex control algorithm switching devices.

 The closest technical solution - the prototype is a flat microstrip antenna array (patent of the Russian Federation N 2087058, class H 01 Q 1/38 C1, 1997), containing an odd number of emitters made in the form of a rectangle, the centers of which are located in the nodes of the rectangular coordinate the grid and are separated by gaps of the same width, the sides of the emitters are parallel to the corresponding axes of this coordinate grid, while the central emitter is made in the form of a square, the side of which is half d in other words, the middle emitters of one and the other central branches of a rectangular coordinate grid, respectively, in the form of a rectangle, one side of which parallel to the corresponding central branch of a rectangular coordinate grid is equal to the wavelength, and the other side of the emitter adjacent to it is equal to half the wavelength, the rest of the emitters are flat the antenna array is made in the form of a square, the side of which is equal to the wavelength, while the exciting element of the Central emitter is connected in one corner at the intersection excitation of one and the other of its adjacent sides, and to each middle emitter of one and the other central branches of a rectangular coordinate grid at a point located on the middle of the side with a length equal to the wavelength and lying on a straight line with one and the other adjacent sides of the central emitter, respectively, exciting elements identical to the exciting element of the central emitter, one ends of which are galvanically connected to the respective emitters, the second ends of the exciting elements of the central and middle to the emitters of a flat microstrip antenna array are galvanically connected to an input power wiring made in the form of a crosswise orthogonal connection of four segments of microstrip lines whose axes are paired and parallel to the central branches of a rectangular coordinate grid, respectively, while the dielectric substrate of the power wiring is installed parallel to the dielectric substrate of a flat microstrip antenna array, and in the center of the cross-shaped connection of four cut For microstrip lines, the second end of the exciting element of the central emitter is turned on, and the second ends of the exciting elements of the middle emitters of one and the other central branches of the rectangular coordinate grid are included in the corresponding segments of the microstrip lines of the crosswise connection along the axial lines, while the segment of the input transmission is connected to the continuation of one of four segments microstrip lines of the cruciform connection, and the length of the remaining three segments of microstrip lines is limited to connecting the second end of the corresponding driving element extreme secondary emitter branches of the central rectangular grid.

The disadvantages of the known technical solutions are:
- the impossibility in the reception mode of the antenna array to decompose the received wave into two orthogonally polarized components and select them in different receiving channels;
- the impossibility in the radiation mode of the antenna array to carry out a change in the polarization of the signal — linear vertical or horizontal or to generate a circular signal with a right-left-left direction of rotation of the polarization vector.

 The technical task of this invention is the creation of a microstrip antenna array, in a single aperture of which two sublattices are placed: - a transmitting sublattice that emits a signal with linear vertical or horizontal polarization or circular with right or left direction of rotation of the polarization vector; - a receiving sublattice, which ensures the decomposition of the received wave into two orthogonally polarized components and their selection in different output channels.

 The problem is solved in that in a microstrip antenna array containing emitters made in the form of a rectangle, the centers of which are located in the nodes of the rectangular coordinate grid, and separated by gaps on each branch of the rectangular coordinate grid, and the sides of the emitters are parallel to the corresponding branches of this rectangular coordinate mesh, while the middle emitters of four mutually perpendicular pairs of rays of a rectangular coordinate grid, respectively, are made in the form a rectangle whose side parallel to the corresponding beam of the rectangular grid is equal to the wavelength, and the other side of the middle emitter adjacent to it is equal to half the wavelength, the remaining emitters of the microstrip antenna array are made in the form of a square, the side of which is equal to the wavelength, with each average to the radiator of four mutually perpendicular pairs of rays of a rectangular coordinate grid at a point located in the middle of the side with a length equal to the wavelength, exciting elements are connected nt made in the form of metal pins, one ends of which are galvanically connected to the corresponding middle emitters, and the second ends are galvanically connected to a power wiring made in the form of four mutually perpendicular pairs of microstrip lines, the axes of which are parallel to four mutually perpendicular pairs of medium emitters of a rectangular grid, respectively, the dielectric substrate of the power wiring is installed parallel to the micro dielectric substrate strip antenna array, while the second ends of the exciting elements of the middle emitters of four mutually perpendicular pairs of rays of a rectangular coordinate grid are included in the corresponding segments of the microstrip power distribution lines along the axial lines, a segment of the output transmission line is connected to the continuation of the first segment of the microstrip power distribution line, the number of emitters of the microstrip antenna the gratings are chosen even, while the four middle emitters, respectively, of four are mutually perpendicular x in pairs of rays of a rectangular coordinate grid closest to the origin of the microstrip antenna array, are arranged in the form of a square, the side of which is formed by two external, with respect to the origin of the coordinates of the microstrip antenna array, sides of two middle emitters, one side equal to the wavelength, one middle emitter and one side equal to half the wavelength of the other middle emitter of two mutually perpendicular pairs of rays of a rectangular coordinate grid, respectively, with each of The four middle emitters closest to the origin of the microstrip antenna array, along the midline parallel to the side equal to the wavelength, are galvanically connected by the contact element to the earth surface of the microstrip antenna array, with the outer sides equal to the wavelength of the four middle emitters closest to the origin microstrip antenna array, and the corresponding system of medium emitters, respectively, of four mutually perpendicular pairs of rays of a rectangular coordinate grid are located on the corresponding rays of the rectangular coordinate grid, and to these sides are connected exciting elements that are connected to the power distribution, and to the inner sides equal to the wavelength of each of the four middle emitters closest to the origin of the microstrip antenna array, segments of input transmission lines are connected and the length of four mutually perpendicular pairs of microstrip power distribution lines on one side is limited by the connection point of the second end of the exciting ementa four secondary emitters four mutually perpendicular pairs of rays of a rectangular grid, the nearest to the origin of a microstrip antenna array, respectively, and to continue the second, third and fourth perpendicular pairs of microstrip segments are connected supply wiring lines of the second, third and fourth segments of the output transmission lines.

 The microstrip antenna array structurally consists of two sublattices in a single aperture - transmitting and receiving. The aperture of the antenna array is two independent mutually perpendicular systems of emitter lines, the longitudinal axes of which are parallel to the corresponding rays of the rectangular coordinate grid. Each line of emitters consists of a chain of electromagnetically coupled passive emitters in the form of a square with a side equal to the wavelength, and an average active emitter in the form of a rectangle with sides equal to the length and half the wavelength, respectively. The middle emitter is connected by an exciting element to the corresponding segment of the microstrip power distribution line. Each system of emitter lines has only that direction of orientation of the linear polarization vector of the electric field, in which the longitudinal axis of the emitter line is parallel to the corresponding ray of the rectangular coordinate grid. Since each square-shaped radiator of a microstrip antenna array is simultaneously a part of one and the other systems of emitter lines, oscillations of two independent and orthogonal linear polarizations, vertical and horizontal, with their amplitudes and phases, can be simultaneously excited in each square-shaped radiator. Each line of average active emitters of the corresponding beam of a rectangular coordinate grid is combined by a corresponding segment of the microstrip power distribution line with the output transmission line connected to it. The first and third line of middle emitters, the corresponding rays of which are parallel to each other, are adequate to the vertical, and the second and fourth line of middle emitters, whose corresponding rays are parallel to each other, of the horizontal component of the linear polarization vector of the electric field of the microstrip antenna array.

In the radiation mode, the transmitting sublattice, consisting of four middle emitters closest to the origin of the antenna array, with equal-amplitude excitation and depending on the phase of the microwave signal supplied to each of the four input lines, generates electromagnetic radiation of a given type of polarization. So, for example, a transmitting sublattice: with a phase distribution of 0 ^o , 180 ^{o the} excitation of the first and third middle emitters, respectively, and the second and fourth connection to a matched load - emits a vertical polarization signal; with a phase distribution of 0 ^o , 180 ^{o the} excitation of the second and fourth middle emitters, respectively, and the first and third connection to a matched load - emits a horizontal polarization signal; when the phase distribution of 0 ^o , 90 ^o , 180 ^o , 270 ^o respectively the first, second, third and fourth middle emitters emits a circular polarization signal of the right-hand direction of rotation of the electric field vector; with a phase distribution of 270 ^o , 180 ^o , 90 ^o , 0 ^o - circular polarization of the left-hand direction.

 In reception mode, a polarized electromagnetic wave is incident on the aperture of the receiving sublattice. On microstrip radiators, the vector of the electric field strength of the received signal is decomposed as a superposition of two-coordinate oriented, in the adopted rectangular coordinate grid, into two coordinate components of the signal - vertical and horizontal, each of which excites the corresponding system of emitter lines with subsequent row-by-column and column-wise summation in the corresponding for each rulers of the average active emitter. The summation of the signals from the middle emitters occurs in the corresponding segment of the microstrip power distribution line, and the resulting amplitude and phase components of the received signal, adequate to the vertical and horizontal components of the received signal, enter the corresponding four segments of the output transmission lines.

 The microstrip antenna array can be connected to four lines of extreme passive emitters made in the form of a square with a side equal to the wavelength of four lines of emitters made in the form of a square with a side equal to the wavelength identical to the passive emitters in the form of a square of the microstrip antenna . The centers of the introduced emitters are located in the nodes of the rectangular coordinate grid of the microstrip antenna array, while the introduced four lines of emitters are installed on the outside of the four lines of extreme emitters, respectively, with the first line of introduced emitters installed to the first line of emitters bounded by the first and second mutually perpendicular rays of the rectangular coordinate grid, the longitudinal axis of which is parallel to the first ray of the rectangular coordinate grid, the second ruler a set of emitters is installed to the second line of emitters bounded by the second and third mutually perpendicular beams of a rectangular coordinate grid, the longitudinal axis of which is parallel to the second beam of a rectangular coordinate grid, a third line of introduced emitters is installed to a third line of emitters bounded by a third and fourth mutually perpendicular beams of a rectangular coordinate grid whose longitudinal axis is parallel to the third ray of the rectangular grid, the fourth ruler is introduced emitters installed to the fourth line of emitters, bounded by the fourth and first mutually perpendicular rays of the rectangular coordinate grid, the longitudinal axis of which is parallel to the fourth ray of the rectangular coordinate grid, while the number of square emitters enclosed in the respective mutually perpendicular pairs of rays of the rectangular coordinate grid is the same and equal to the number emitters in the row and in the column, and the gaps separating the emitters from each branch of the rectangular to coordinate grid, made of the same width.

 This embodiment of the microstrip antenna array creates the symmetry of the aperture, which allows for: accurate reproduction of the specified polarization characteristics; a high degree of symmetry of the amplitude distribution over the aperture of the receiving sublattice relative to the average active emitters; full symmetry of the antenna array radiation pattern in orthogonal planes of a rectangular coordinate grid; low level of side lobes.

 The microstrip antenna array can be equipped with a polarization conversion unit (BPP) of the receiving sublattice, which can be made up of the first and second phase shifters, the output channels of which are connected to the input channels of the first and second three-decibel power dividers, respectively, the output channels of which are the input channels of the BPP, which connected to the corresponding output lines of the power wiring of the microstrip antenna array, and the input channels of the first and second phase shifters i lyayutsya output channels orthogonally polarized microstrip antenna array PPO.

 The introduction of the BPP into the microstrip antenna array provides the receiving sublattice with a decomposition of the received wave into two orthogonally linearly polarized components and can direct each of the selected polarization signal components to the corresponding output polarization channel.

 The microstrip antenna array can be equipped with a polarization control unit (PCU) of the transmitting sublattice, which can be made up of a first three-decibel power divider, one output channel of which is connected to the input channel of the first phase shifter, and its other output channel and output channel of the first phase shifter are connected to the input and decoupled channels of a three-decibel directional coupler, respectively, the passage and connected channels of which are connected to the input channels of the first and second switches, respectively, whose first output channels are connected to matched loads, and the second output channels are connected to the input channels of the second and third phase shifters, respectively, the output channels of which are connected to the input channels of the second and third three-decibel power dividers, respectively, the output channels of the second and third three-decibel power dividers are BUP output channels that are connected to the segments of the input transmission lines of the four middle emitters of the microstrip antennas th grating, respectively, and the input channel of the first power divider is trehdetsibelnogo inlet BUP microstrip antenna array.

 The introduction of the PDU into the microstrip antenna array provides the transmitting sublattice with the radiation modes of the signal with linear vertical or horizontal polarization, or circular with right or left direction of rotation of the polarization vector.

 In FIG. 1 shows the design of a microstrip antenna array; figure 2 - design of a microstrip antenna array with a symmetrical aperture; in FIG. 3 - power wiring design of the microstrip antenna array; figure 4 - design of a metal screen separating the dielectric substrate of the antenna array and power wiring; in FIG. 5 - design of the contact element in the form of a metal plate; figure 6 - design of the contact element in the form of metal pins; on the. FIG. 7 is a block diagram of a polarization conversion unit (BPP); in Fig.8 is a structural diagram of a polarization control unit (BUP).

 The microstrip antenna array 1 (Fig. 1) contains an even number of emitters made in the form of a rectangle, the centers of which are located in the nodes of the rectangular coordinate grid, and separated by the gaps 2 and 3 on each branch of the rectangular coordinate grid, respectively, and the sides of the radiators are parallel to the corresponding branches of this rectangular grid. The middle emitters 4 of four mutually perpendicular pairwise rays 5, 6, 7 and 8 of a rectangular coordinate grid, respectively, are made in the form of a rectangle, one side 9 of which, parallel to the corresponding ray 5, 6, 7, 8 of a rectangular coordinate grid, is equal to the wavelength, and the other adjacent with it, the side 10 of the emitter 4 is equal to half the wavelength, the remaining emitters 11 of the microstrip antenna array 1 are made in the form of a square, side 12 of which is equal to the wavelength. For each middle emitter 4 of four mutually perpendicular pairs of rays 5, 6, 7, 8 of a rectangular coordinate grid at a point located on the middle of the lateral edge 9 with a length equal to the wavelength, exciting elements 13 are made in the form of a metal pin, one ends of which are connected with the corresponding middle emitters 4, and the second ends are galvanically connected to the power distribution 14. Four middle emitters 15, respectively, of four mutually perpendicular beams 5, 6, 7, 8 of a rectangular coordinate grid nearest to the origin of the microstrip antenna array 1, are arranged in the form of a square, each side of which is formed by two external, with respect to the origin of the coordinates of the microstrip antenna array 1, the sides of two middle emitters 15, one side 9 of a length equal to the wavelength of one middle emitter 15 and the other side 10 with a length equal to half the wavelength of the other middle emitter 15 of two mutually perpendicular rays 5 and 6, 6 and 7, 7 and 8 of 8 and 9 of the rectangular coordinate grid, respectively. Each of the four middle emitters 15, closest to the origin of the microstrip antenna array 1, along a midline parallel to side 9 of the same wavelength, is galvanically connected by the contact element 16 to the ground surface 17 of the microstrip antenna array 1, while the outer sides 9 of length equal to the wavelength of the four middle emitters 15, closest to the origin of the microstrip lattice 1, and the corresponding line of middle emitters 4, respectively, of four mutually perpendicular pairs of rays 5, 6, 7 and 8 directly of the carbon coordinate grid are located on the corresponding beams 5, 6, 7 and 8 of the rectangular coordinate grid, and to these lateral edges 9 are connected exciting elements 13 that are connected to the power supply 14. To the inner sides 18 with a length equal to the wavelength of each of the four middle emitters 15, closest to the origin of the microstrip antenna array 1, connected segments of the input transmission lines 19, 20, 21 and 22, respectively. The power distribution 14 is made in the form of four mutually perpendicular pairs of microstrip lines 23, 24, 25 and 26, the axes of which are parallel to the four mutually perpendicular pairs of rays 5, 6, 7 and 8 of the middle emitters 4 of a rectangular coordinate grid, respectively, the dielectric substrate of the power distribution 14 installed parallel to the dielectric substrate of the microstrip antenna array 1, while the second ends of the exciting elements 13 of the middle emitters 4 of four mutually perpendicular pairs of beams 5, 6, 7 and 8 pr the rim of the grid are included in the respective mutually perpendicular pairs of microstrip lines 23, 24, 25 and 26 of the power distribution 14 along the axial lines. The length of four mutually perpendicular pairs of segments 23, 24, 25 and 26 of the microstrip power supply lines 14 on one side is limited by the connection point of the second end of the exciting element 13 of the four middle emitters 15 closest to the origin of the microstrip antenna array 1, respectively, and to the continuation of four mutually perpendicular in pairs of segments of microstrip lines 23, 24, 25 and 26 of the power distribution 14, segments of 27, 28, 29 and 30 of the input transmission lines are connected, respectively. The dielectric substrate of the power supply 14 and the dielectric substrate of the antenna array 1 are separated by a common metal screen 17, in which round holes 31 are formed at the locations of the exciting elements 13 and segments of the input transmission lines 19, forming segments of inter-level coaxial junctions.

 In the microstrip antenna array 1 (Fig. 2) to four lines of extreme passive emitters 11, made in the form of a square, from the side of their outer sides 12 are connected four systems of emitters 32, 33, 34 and 35, identical to the passive emitters 11, the centers of which are located in the coordinate system of the microstrip antenna array 1. The first system of emitters 32 is installed on the first line of emitters 11, bounded by the first 5 and second 6 mutually perpendicular beams of a rectangular coordinate grid, the longitudinal axis of which is parallel to the first I’m learning 5 a rectangular coordinate grid, the second line of emitters 33 is installed to the second line of emitters 11, bounded by the second 6 and third 7 mutually perpendicular beams of the rectangular coordinate grid, the longitudinal axis of which is parallel to the second beam 6 of the rectangular coordinate grid, the third line of emitters 34 is installed to the third line of emitters 11 bounded by the third 7 and fourth 8 mutually perpendicular rays of a rectangular coordinate grid, the longitudinal axis of which is parallel to the third 7 beam grid, the fourth line of emitters 35 mounted to the emitters of the fourth line 11, the fourth limited to the first 5 and 8 are mutually perpendicular beams rectangular grid, which is parallel to the longitudinal axis of the fourth beam 8 rectangular grid. The number of square emitters 32, 33, 34 and 35, enclosed in the corresponding mutually perpendicular pairwise rays 5 and 6, 6 and 7, 7 and 8, 8 and 5 of a rectangular coordinate grid, is the same, and the number of emitters in a row is equal to the number of emitters in a column . The gaps 2 and 3, dividing the emitters between each branch of a rectangular coordinate grid, respectively, are made of the same width.

 BPP (Fig. 7) consists of the first 32 and second 33 phase shifters, the output channels of which are connected to the input channels of the first 34 and second 35 three-decibel power dividers, respectively, the output channels of which are the input channels of the BPP, which are connected to the corresponding output transmission lines 27, 28 , 29 and 30 of the power distribution 14 of the microstrip antenna array 1, and the input channels of the first 32 and second 33 phase shifters are the output orthogonally polarized channels of the BPP microstrip array 1.

 BUP (Fig. 8) consists of a first three-decibel power divider 36, one output channel of which is connected to the input channel of the first phase shifter 37, and its other output channel and output channel of the first phase shifter 37 are connected to the input and decoupled channels of the three-decibel directional coupler 38, respectively, a passage and the associated channels of which are connected to the input channels of the first 39 and second 40 switches, respectively, the first output channels of which are connected to the matched loads 41 and 42, and the second output channels the channels are connected to the input channels of the second 43 and third 44 phase shifters, respectively, the output channels of which are connected to the input channels of the second 45 and third 46 three-decibel power dividers, respectively, the output channels of the second 45 and third 46 three-decibel power dividers are output channels of the BCU, which are connected to the input transmission lines 19, 20, 21 and 22 of the four middle emitters 15 of the microstrip antenna array 1, respectively, and the input channel of the first three-decibel power divider 36 is the input channel BUP microstrip antenna array 1.

 Microstrip lattice operates as follows.

In the radiation mode, for each of the four input transmission lines 19, 20, 21 and 22 of the four middle emitters 15 of the transmitting sublattice, the microstrip antenna array 1 delivers an equal-amplitude signal with a phase distribution corresponding to a given type of polarization of the resulting emitted electromagnetic field. So, for example, a transmitting sublattice: with a phase distribution of 0 ^o , 180 ^o on the input transmission lines 19 and 21 of the excitation of the first and third middle emitters, respectively, and the second and fourth 20 and 22 connected to a matched load - emits a vertical polarization signal; when the phase distribution of 0 ^o , 180 ^o on the input transmission lines 20 and 22 of the excitation of the second and fourth middle emitters, respectively, and the first and third 19 and 21 connected to the matched load - emits a horizontal polarization signal; when the phase distribution is 0 ^o , 90 ^o , 180 ^o and 270 ^o, respectively, the first 19, second 20, third 21 and fourth 22 input transmission lines of the middle emitters emits a circular polarization signal of the right-hand direction of rotation of the electric field vector; when the phase distribution of 270 ^o , 180 ^o , 90 ^o , 0 ^o respectively 19, 20, 21 and 22 of the input transmission lines emits a circular polarization signal of the left-hand direction of rotation.

 In the reception mode, a polarized, with any type of polarization, electromagnetic wave is incident on the aperture of the receiving sublattice of the microstrip antenna array 1. On microstrip emitters 4, 15, and 11, the vector of the electric field strength of the received signal is decomposed as a superposition of two-coordinate oriented, in the received rectangular coordinate grid of the microstrip antenna array 1, into two coordinate components of the signal in the rectangular coordinate grid of the antenna array 1: one is a projection parallel to the rays 5 and 7 and corresponds to the horizontal component; the other is a projection parallel to beams 6 and 8 and corresponds to the vertical component. Each of the signal components excites its corresponding system of emitter lines 11. The resulting signal from the emitter line is extracted on the corresponding active average emitter 4 of the beam 5, 6, 7, 8 of a rectangular coordinate grid, respectively. Through the exciting elements 13, the signal from the middle emitters 4 enters the corresponding segments of the microstrip lines 23, 24, 25 and 26 of the power distribution 14. Since the distance between the exciting elements 13 is equal to or a multiple of the wavelength, then in the segments of the microstrip lines 23, 24, 25 and 26 of the power wiring 14, in-phase summation of the signals from the middle emitters connected to them occurs 4. The resulting signal from the segments of the microstrip lines 21, 22, 23, and 24 enters the output transmission lines 25, 26, 27, and 28, respectively. The resulting amplitude and phase components in the output transmission lines 25, 26, 27 and 28 are adequate to the vertical and horizontal components of the received signal.

 In the microstrip antenna array 1 (Fig. 2), the connection of four systems of emitters 32, 33, 34 and 35 and the equality of the emitters 11 in the row and in the column are enclosed in the respective mutually perpendicular pairs of beams 5 and 6, 6 and 7, 7 and 8 , 8 and 9 of a rectangular coordinate grid, provide in reception mode: exact reproduction of the set polarization characteristics, complete symmetry of the antenna array pattern in orthogonal planes, low level of side lobes.

 When connecting the BPP (Fig.7) to the receiving sublattice microstrip antenna array 1 operates as follows. The signals from the output transmission lines 27 and 29 of the components of vertical polarization, 28 and 30 of the components of horizontal polarization, power wiring 14 are fed to the input channels of the first 34 and second 35 three-decibel power dividers, respectively, where they are in-phase summed and output from the output channels through phase shifters 32 and 33, respectively on the weekend orthogonally polarized channels of the BPP microstrip antenna array.

When connecting the PCU (Fig. 8) to the transmitting sublattice, the microstrip antenna array 1 operates as follows. The input signal is fed to the input channel of a three-decibel power divider 36, from the output channels of which one is through a phase shifter 37, and the other directly goes to the input and decoupled channels of a three-decibel directional coupler 38. The phase shifter 37 is set in three operating modes, each of which corresponds to a certain polarization characteristic of the transmitting sublattices. The first mode is an equal-amplitude signal from the through and connected output channels of the directional coupler 38, respectively, through series-connected first switch 39 and second phase shifter 43, second switch 40 and third phase shifter 44 with phase distribution 0 ^o , 90 ^o , 180 ^o , 270 ^o or phase distribution 270 ^o, 180 ^o, 90 ^o, 0 ^o enters the second input channels, respectively 45 and 46 trehdetsibelnyh third power dividers, output channels are connected to inlets 27, 28, 29 and 30 of the power distribution antenna 14 dec weave 1, and it corresponds to left-hand circular polarization or right-handed. The second and third modes of operation correspond to linear horizontal or vertical polarization of the signal, respectively, which is achieved by completely redistributing power between the pass-through and connected channels of the directional coupler 38 and switches 39 and 40. Horizontal polarization mode - the signal is fed to the output channels 28 and 30, and channels 27 and 29 are switched by a switch 39 to the matched load 41. In the vertical polarization mode, the signal is fed to the output channels 27 and 29, and channels 28 and 30 are switched by tel 40 to the agreed load 42.

Claims (8)

 1. Microstrip antenna array containing emitters made in the form of a rectangle, the centers of which are located in nodes of a rectangular coordinate grid and separated by gaps on each branch of a rectangular coordinate grid, and the sides of the emitters are parallel to the corresponding branches of this rectangular coordinate grid, while the middle radiators of four perpendicular rays of a rectangular coordinate grid, respectively, are made in the form of a rectangle, one side of which is parallel to the corresponding beam of a rectangular coordinate grid is equal to the wavelength, and the other side of the middle emitter adjacent to it is equal to half the wavelength, the remaining emitters of the microstrip antenna array are made in the form of a square, the side of which is equal to the wavelength, with four perpendicular rays to each middle emitter of a rectangular coordinate grid at a point located in the middle of the side with a length equal to the wavelength, exciting elements made in the form of metal pins, one ends of which are connected are connected galvanically to the respective middle emitters, and the second ends are galvanically connected to a power wiring made in the form of four perpendicular segments of microstrip lines, the axes of which are parallel to the four perpendicular rays of the middle emitters of a rectangular coordinate grid, respectively, the dielectric substrate of the power wiring is installed parallel to the dielectric substrate of the microstrip antenna array while the second ends of the exciting elements of the middle emitters three perpendicular rays of a rectangular coordinate grid are included in the corresponding segments of the microstrip power distribution lines along the axial lines, a segment of the output transmission line is connected to the continuation of one segment of the microstrip power distribution line, characterized in that the microstrip antenna array contains an even number of emitters, with four middle emitters, respectively four perpendicular rays of a rectangular coordinate grid closest to the origin of the microstrip antenna The grids are arranged in the shape of a square, each side of which is formed by the two sides of two middle emitters, one side equal to the wavelength, one middle emitter and one side equal to half the wavelength of the other middle emitter of two perpendicular to each other with respect to the origin of the microstrip antenna array rays of a rectangular coordinate grid, respectively, with each of the four middle emitters closest to the origin of the microstrip antenna array along the midline parallel the other side, equal to the wavelength, is galvanically connected by the contact element to the ground surface of the microstrip antenna array, while the outer sides, equal to the wavelength of the four middle emitters closest to the origin of the microstrip antenna array, and the corresponding system of average emitters, respectively, of four perpendicular rectangular coordinate beams the grids are located on the corresponding rays of the rectangular coordinate grid and exciting elements are connected to these sides, which segments with power wiring, and to the inner sides equal to the wavelength of each of the four middle emitters closest to the origin of the microstrip antenna array, segments of input transmission lines are connected, and the length of four perpendicular segments of microstrip power wiring lines is limited on one side by the connection point of the second end the exciting element of the four middle emitters of four perpendicular rays of a rectangular coordinate grid closest to the origin of the microstrip ant lattice constant, respectively, and to continue the second, third and fourth microstrip lines perpendicular segments connected power distribution introduced second, third and fourth segments of the output transmission lines.  2. The microstrip antenna array according to claim 1, characterized in that four introduced systems of emitters made in the form of a square with a side equal to the wavelength are connected to the four lines of the extreme passive emitters made in the form of a square with a side equal to the wavelength emitters in the form of a square with a side equal to the wavelength of the microstrip antenna array, the centers of the introduced emitters are located in the nodes of the rectangular coordinate grid of the microstrip antenna array, and the four systems introduced The emitters are installed on the outer side of the four lines of extreme emitters, respectively, with the first system of introduced emitters installed on the first line of emitters bounded by the first and second perpendicular beams of the rectangular coordinate grid, the longitudinal axis of which is parallel to the first beam of the rectangular coordinate grid, the second system of introduced emitters is installed to the second line of emitters, limited by the second and third perpendicular rays of a rectangular coordinate grid, about the longitudinal axis of which is parallel to the second ray of the rectangular coordinate grid, the third system of introduced emitters is installed to the third line of emitters, limited by the third and fourth perpendicular rays of the rectangular coordinate grid, the longitudinal axis of which is parallel to the third ray of the rectangular coordinate grid, the fourth system of introduced emitters is installed to the fourth line of emitters, bounded by the fourth and first perpendicular rays of a rectangular coordinate grid, the longitudinal axis of which parallel to the fourth ray of the rectangular coordinate grid, while the number of square emitters enclosed in the corresponding perpendicular rays of the rectangular coordinate grid is the same and the number of emitters in the row is equal to the number of emitters in the column, and the gaps separating the emitters along each branch of the rectangular coordinate grid, made of the same width.  3. The microstrip antenna array according to claim 1, characterized in that the contact element is made in the form of a metal plate.  4. The microstrip antenna array according to claim 1, characterized in that the contact element is made in the form of a series of metal pins.  5. The microstrip antenna array according to claim 1, characterized in that a polarization conversion unit (BPP) is introduced, the input channels of which are connected to the output power transmission lines of the microstrip antenna array, and the first and second output channels of the BPP are output orthogonally polarized channels of the microstrip antenna lattice.  6. The microstrip antenna array according to claim 5, characterized in that the BPP consists of first and second phase shifters, the output channels of which are connected to the input channels of the first and second three-decibel power dividers, respectively, the output channels of which are the input channels of the BPP, which are connected to the corresponding output power transmission lines of the microstrip antenna array, and the input channels of the first and second phase shifters are the output orthogonally polarized channels of the BPP of the microstrip antenna ennoy lattice.  7. The microstrip antenna array according to claim 1, characterized in that a polarization control unit (FCU) is introduced, the output channels of which are connected to the segments of the input transmission lines of the four middle emitters of the microstrip antenna array, respectively, and the input channel of the FCU is the input channel of the microstrip antenna array.  8. The microstrip antenna array according to claim 7, characterized in that the ECU consists of a first three-decibel power divider, one output channel of which is connected to the input channel of the first phase shifter, and its other output channel and the output channel of the first phase shifter are connected to the input and decoupled channels of the three-decibel a directional coupler, respectively, the through and connected channels of which are connected to the input channels of the first and second switches, respectively, whose first output channels are connected to combined loads, and the second output channels are connected to the input channels of the second and third phase shifters, respectively, the output channels of which are connected to the input channels of the second and third three-decibel power dividers, respectively, the output channels of the second and third three-decibel power dividers are output channels of the BCU, which are connected to the input transmission lines of four middle emitters of a microstrip antenna array, respectively, and the input channel of the first three-decibel divider a power inlet BUP microstrip antenna array.

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