RU216808U1 - ANTENNA - Google Patents

Abstract

The utility model relates to antenna technology, in particular to ultra-wideband microwave antennas, and can be used as an independent receiving or transmitting antenna, as well as a subantenna as part of phased antenna arrays, in metrology, in communication systems, in radio flaw detection, in radio monitoring , in problems of electromagnetic compatibility. The technical result of the utility model is the expansion of the operating frequency band of the antenna, which is achieved due to the fact that the antenna containing a dielectric base with a slotted recess made in it, expanding towards the end face of the dielectric base, and the profile of the slotted recess on one side of the dielectric base is formed by two flat lines and with a straight line of the gap, also on the dielectric base in the area of the slot recess, the upper and lower electrodes are mounted, each of which consists of two identical metal plates mounted oppositely, opposite each other on different sides of the dielectric base and galvanically connected to each other, while one of the faces metal plates and the corresponding flat line of the profile of the slotted recess are identical in shape and coincide when mounting the electrodes, characterized in that the profile of the slotted recess is made in such a way that it does not change along the thickness of the dielectric base, but for the galvanic To connect the metal plates of the upper and lower electrodes, an electrically conductive layer is used, deposited along the thickness of the dielectric base between the flat lines of the slit recess. 3 w.p. f-ly, 3 ill.

Description

The utility model relates to antenna technology, in particular to ultra-wideband microwave antennas, and can be used as an independent receiving or transmitting antenna, as well as a subantenna as part of phased antenna arrays, in metrology, in communication systems, in radio flaw detection, in radio monitoring , in problems of electromagnetic compatibility [H01Q 9/28, H01Q 13/08, H01Q 13/10, H01Q 13/20].

The prior art known ANTENNA [GB 1601441 A, publ. 10/28/1981], which is made on a dielectric substrate based on a printed symmetrical slot line, exponentially expanding from the input transmission line to the antenna opening. The transition from a symmetrical slot line to a coaxial connector is carried out through a microstrip line installed orthogonally with respect to the symmetrical slot line and located on the other side of the dielectric substrate. In this antenna, the formation of an electromagnetic field begins in the dielectric, and only in the process of propagation of an electromagnetic wave does it go beyond the dielectric and enter the surrounding space.

The disadvantage of the analogue is the decrease in efficiency in the high-frequency part of the range due to the absorption of the electromagnetic field in the dielectric.

The prior art also known BROADBAND TRANSITION FROM MICROSTRIP LINE TO SLOT LINE [US 5278575 A, publ. 01/11/1994], made on the basis of the antipodal slot line (APSL). The antenna aperture is formed by a segment of the printed ASL without overlap and contains two identical metal plates located on different sides of the dielectric substrate. In the radiating part of the printed antenna, the APSL metal plates are made exponentially expanding along the inner side edge from the point of zero overlap to the maximum aperture opening. The signal strip conductor of the segment of the microstrip line is galvanically connected to the inner side edge of one APSL metal plate in the zero overlap area, and its ground plane is galvanically connected to the end side edge of the other APSL metal plate in the zero overlap area.

The disadvantages of the analogue is the increase in size due to the protruding elements in the form of metal plates, as well as the decrease in efficiency in the high-frequency part of the range due to the absorption of the electromagnetic field in the dielectric between the plates.

The closest in technical essence is PRINTED ANTENNA [RU 2400876 C1, publ. 09/27/2010], containing a segment of the antipodal slot line located on a dielectric substrate, and a segment of the signal strip line, while the antenna aperture is formed by a segment of the antipodal slot line without overlap in the interval from the zero overlap region to the region of maximum aperture opening, the same signal and ground metal the plates of which are made tapering along the inner side edge from the area of zero overlap to the area of maximum aperture opening, the segment of the signal strip line is placed on one surface of the dielectric substrate and the end face is galvanically connected to the inner side edge of the signal metal plate in the area of zero overlap of the signal and ground metal plates, and the ground plane of the segment of the signal strip line is located on the other, opposite surface of the dielectric substrate in the area of zero overlap of the antipodal slot line and is galvanically connected to the end cap. an edge edge of an earth metal plate, characterized in that a segment of an additional antipodal slot line without overlap is introduced, the first and second metal plates of which are identical to the signal and earth metal plates, respectively, and the first metal plate is located on the same surface of the dielectric substrate in the area of the aperture with the signal metal plate , and the second metal plate is located on the same surface of the dielectric substrate in the area of the aperture with the ground metal plate, while the segment of the additional antipodal slot line without overlap does not have a zero overlap area, and in the aperture area the first metal plate is galvanically connected by metal jumpers to the ground metal plate, and the second metal plate is galvanically connected by metal jumpers to the signal metal plate.

The main technical problem of the prototype is the narrowing of the operating frequency band of the antenna due to the absorption of the electromagnetic field in the dielectric.

The purpose of the utility model is to eliminate the shortcomings of the prototype.

The technical result of the utility model is to expand the operating frequency band of the antenna.

This technical result is achieved due to the fact that the antenna containing a dielectric base with a slotted recess made in it, expanding towards the end of the dielectric base, and the profile of the slotted recess on one side of the dielectric base is formed by two flat lines and a straight line of the gap, also on the dielectric base in top and bottom electrodes are mounted in the slot recess area, each of which consists of two identical metal plates mounted oppositely, opposite each other on different sides of the dielectric base and galvanically connected to each other, while one of the faces of the metal plates and the corresponding flat line of the slotted profile recesses are identical in shape and coincide when mounting the electrodes, characterized in that the profile of the slotted recess is made in such a way that it does not change along the thickness of the dielectric base, and for galvanic connection of the metal plates of the upper and lower electrodes uses an electrically conductive layer deposited across the thickness of the dielectric base between the flat lines of the slit recess.

In particular, the slit recess has a symmetrical profile.

In particular, the slit recess partly contains a dielectric base material.

In particular, the dielectric material forms a dielectric strip in the wide part of the slot recess.

Brief description of the drawings.

Figure 1 shows a General view of the antenna (version with jumpers).

Figure 2 shows a General view of the antenna (version with a conductive layer).

Figure 3 shows a general view of the antenna (version with a conductive layer and a dielectric strip).

The figures indicate: 1 - dielectric base, 2 - slot notch, 3 - gap, 4 - flat lines, 5 - top electrode, 6 - bottom electrode, 7 - jumpers, 8 - electrically conductive layer, 9 - dielectric bar.

Implementation of the utility model

The antenna contains a dielectric base 1 (figure 1), made of a dielectric material in the form of a rectangular plate with a slotted recess 2 (slotted groove) of complex shape implemented at one of its ends, the geometry of which is determined by the characteristics of the antenna and is selected from the ratios adopted for calculating the antennas of this type. The slit recess 2, inside which there is no dielectric material, expands towards the end of the plate and reaches its maximum width at the end of the dielectric base 1, forming the opening of the antenna. As you move away from the end, the width of the slotted recess 2 decreases and at the end becomes equal to the minimum width - the width of the gap 3. Thus, the profile of the slotted recess 2 on one side of the dielectric base 1 is formed by two flat lines 4 and a straight line of the gap 3, and the same profile is also located on the opposite side of the dielectric base 1. Thus, the profile of the slotted recess 2 does not change along the thickness of the dielectric base 1 and is either symmetrical or asymmetrical. The flat lines 4 of the slotted recess 2, depending on the required characteristics of the antenna, are made as follows: exponential, second-order curves, a set of piecewise linear segments, straight lines, etc.

The top 5 and bottom 6 electrodes are mounted on the dielectric base 1 in the area of the slotted recess 2, each of which consists of two identical metal plates (not shown in the figures), mounted oppositely, opposite each other on different sides of the dielectric base 1 and galvanically connected to each other (i.e. directly, without the use of passive and active elements).

The shape of the metal plates can be different, but with the condition that one of their faces corresponds in shape to the flat line 4 of the slotted recess 2, and, therefore, the metal plates are mounted on the dielectric base 1 in such a way that the contour of the slotted recess 2 and this face of the metal plate coincide.

Figures 1, 2 and 3 show a symmetrical slit recess 2 formed by flat lines 4 of exponential type, and the shape of the metal plates of the upper 5 and lower electrodes 6 is similar to a right triangle, in which the hypotenuse instead of a straight line is an exponential curve.

The size of the gap 3 is determined, among other things, from the condition of preventing a short circuit of the electrodes 5 and 6. The power lines are not shown in the figures, since the signal (energy) is supplied to the antenna by any known method, for example, a strip line or a coaxial cable.

In FIG. 1 shows the galvanic connection of two metal plates in the upper 5 and lower 6 electrodes using jumpers 7, that is, the antenna is presented in a version with jumpers 7, while the number of jumpers 7 does not affect the achievement of the technical result and may be different.

In the antenna version with an electrically conductive layer 8 (figure 2), instead of jumpers 7 for galvanic connection of the metal plates of the upper 5 and lower electrodes 6, an electrically conductive layer 8 is used, deposited along the thickness of the dielectric base 1 between the flat lines 4 of the slot recess 2. This electrically conductive layer 8 , made of metal and applied, for example, by spraying.

The antenna presented in figure 3 in the version with an electrically conductive layer 8 and a dielectric strip 9 differs from the antenna shown in figure 2 in the version with an electrically conductive layer 8 in that, in order to maintain the rigidity of the structure, the dielectric material is partially removed only from the narrow part of the slotted recess 2, which corresponds to for high frequencies, and the wide part, starting from the end, remains filled with a dielectric, that is, there is a dielectric bar 9.

The antenna works as follows.

Depending on the mode of operation, the slit recess 2 is a signal-emitting or signal-receiving part of the antenna. In the narrow part in the region of the gap 3 slot recess 2 has a wave impedance corresponding to the wave impedance of the feed line of the antenna. As the slot recess 2 expands, the wave impedance of the line approaches the wave impedance of the environment, which ensures the transfer of energy to the environment, that is, the radiation of electromagnetic energy. Since the electromagnetic wave moves between the radiating electrodes 5 and 6 outside the dielectric base 1, the characteristics of the dielectric material do not affect the radiating properties of the antenna, which ensures low losses in the region of high radiated frequencies. An even greater reduction in losses is facilitated by the application of an electrically conductive layer 8 to the slotted recess 2.

This antenna can be used as an independent receiving or transmitting unit, and can also be an integral part of the antenna field, or a complex reflector antenna.

The technical result of the utility model - the expansion of the operating frequency band of the antenna, is achieved due to the complete or partial absence of the dielectric material inside the slot recess 2, since in this case the electromagnetic wave moves between the emitting electrodes 5 and 6 outside the dielectric base 1 and, therefore, the characteristics of the dielectric material are not affect the radiating properties of the antenna, which ensures low losses in the region of high radiated frequencies.

Additionally, the antenna performance is improved by applying an electrically conductive layer 8 to the slot recess 2 instead of jumpers 7, since in this case there are no electrode elements 5 and 6 located inside the dielectric material of the dielectric base 1.

In 2022, the author of the utility model manufactured a prototype antenna with an electrically conductive layer 8 and a dielectric strip 9, while despite the use of standard fiberglass as a dielectric material, the antenna operated in the range from 500 MHz to 18 GHz with SWR in the supply no more than 2 lines, which confirmed the compliance of the presented antenna with the ultra-wideband class and the good performance of the antenna in the high frequency region.

Claims (4)

1. An antenna containing a dielectric base with a slotted recess made in it, expanding towards the end of the dielectric base, and the profile of the slotted recess on one side of the dielectric base is formed by two flat lines and a straight line of the gap, and the top and bottom are also mounted on the dielectric base in the area of the slotted recess. electrodes, each of which consists of two identical metal plates, mounted opposite, opposite each other on different sides of the dielectric base and galvanically connected to each other, while one of the faces of the metal plates and the corresponding flat line of the slotted recess profile are identical in shape and coincide with installation of electrodes, characterized in that the profile of the slit recess is made in such a way that it does not change along the thickness of the dielectric base, and for the galvanic connection of the metal plates of the upper and lower electrodes, an electrically conductive layer is used, deposited along the thickness of the die electrical base between the flat lines of the slotted notch. 2. The antenna according to claim 1, characterized in that the slit recess is made with a symmetrical profile. 3. The antenna according to claim 1, characterized in that the slit recess partially contains the dielectric material of the base. 4. The antenna according to claim 3, characterized in that the dielectric material forms a dielectric strip in the wide part of the slot recess.

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