CN215869814U - Metamaterial structure antenna with quasi-rectangular cavity feed - Google Patents

Abstract

The utility model discloses a metamaterial structure antenna with rectangular cavity-like feed, wherein a through long gap is formed in the side of a cavity waveguide, a matching section and a phase gradient super surface are embedded in the long gap, the middle lines of the cavity waveguide, the matching section and the phase gradient super surface are superposed, electromagnetic energy is radiated mainly through the long gaps on the two sides of the cavity waveguide, the phase gradient super surface is excited through radiated energy, the direction of phase gradient is opposite to the direction of energy radiation through the principle of super surface unit radiation, so that the phase gradient super surface radiates energy to free space, and the angle of a wave beam can be controlled at will by adjusting the arrangement of super material units. The metamaterial structure antenna fed by the quasi-rectangular cavity is simple in structure and easy to process, high gain of the antenna can be achieved, and the bandwidth of the antenna can be expanded.

Description

Metamaterial structure antenna with quasi-rectangular cavity feed

Technical Field

The utility model relates to the technical field of antennas, in particular to a metamaterial structure antenna with rectangular cavity-like feed.

Background

Electromagnetic metamaterial technology has been applied to various antenna types for reducing profile, improving gain, reducing radar cross-section, and the like. Among them, the phase gradient super surface is also gradually attracting the interest of the technologists due to the low profile structure. It is used to excite surface plasmons, or to directly generate radiation. There are currently improved rectangular waveguide technology, guided corrugated metal strip technology, etc. for the excitation of radiation.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a metamaterial antenna with similar rectangular cavity feed, which aims to make the structure of the metamaterial antenna with similar rectangular cavity feed simpler and easier to process, realize high gain of the antenna and expand the bandwidth of the antenna.

In order to achieve the purpose, the metamaterial structure antenna fed by the rectangular cavity comprises a feed network, a matching section, a phase gradient super surface and a transition section, wherein the matching section, the phase gradient super surface and the transition section are sequentially arranged on the feed network;

the feed network comprises an SMA connector, a rectangular waveguide and a cavity waveguide, the cavity waveguide is fixedly connected with the rectangular waveguide and is positioned on the side of the rectangular waveguide, the SMA connector is fixedly connected with the rectangular waveguide and is positioned above the rectangular waveguide, and a probe of the SMA connector penetrates through the upper wall of the rectangular waveguide.

The cavity waveguide is characterized in that a through long gap is formed in the side of the cavity waveguide, the matching section and the phase gradient super-surface are embedded in the long gap, and the central lines of the cavity waveguide, the matching section and the phase gradient super-surface are overlapped.

The matching section comprises a matching metal patch, a matching medium substrate and a matching metal ground, the matching metal patch is fixedly connected with the matching medium substrate and is positioned on the upper surface of the matching medium substrate, and the matching metal ground is arranged on the lower surface of the matching medium substrate.

The phase gradient super-surface comprises a plurality of super-material units, a medium substrate and a metal ground, wherein each super-material unit is arranged on the upper surface of the medium substrate, and the metal ground is fixedly connected with the medium substrate and is positioned on the lower surface of the medium substrate.

The metamaterial units are arranged periodically, the distance between every two adjacent metamaterial units is 10mm, and each metamaterial unit is composed of a first unit, a second unit and a third unit.

The transition section is fixedly connected with the phase gradient super surface and is positioned on one side of the phase gradient super surface, which is far away from the matching section.

Wherein the width of the transition section is consistent with the width of the rectangular waveguide.

Wherein the matching dielectric substrate, the dielectric substrate and the transition section have the same thickness dimension.

The radius of the probe of the SMA connector is 0.62mm, the radius of the coaxial shell is 2.03mm, and the length of the coaxial probe is 6.5 mm.

According to the metamaterial structure antenna with the quasi-rectangular cavity feed, the side of the cavity waveguide is provided with a through long gap, the matching section and the phase gradient super-surface are embedded in the long gap, the center lines of the cavity waveguide, the matching section and the phase gradient super-surface are overlapped, electromagnetic energy is radiated mainly through the long gaps on the two sides of the cavity waveguide, the phase gradient super-surface is excited through radiated energy, the direction of the phase gradient is opposite to the direction of energy radiation through the principle of super-surface unit radiation, so that the phase gradient super-surface radiates energy to free space, and the angle of a wave beam can be controlled at will by adjusting the arrangement of the super-material units. The metamaterial structure antenna fed by the quasi-rectangular cavity is simple in structure and easy to process, high gain of the antenna can be achieved, and the bandwidth of the antenna can be expanded.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a top view of a rectangular cavity-like fed metamaterial structure antenna of the present invention.

Fig. 2 is a bottom view of the metamaterial structure antenna fed by the rectangular-like cavity of the present invention.

Fig. 3 is a left side view of the rectangular cavity-like fed metamaterial structure antenna of the present invention.

Fig. 4 is a front view of a rectangular-like cavity fed metamaterial structure antenna of the present invention.

Fig. 5 is a schematic diagram of a metamaterial unit structure of the rectangular cavity-like fed metamaterial structure antenna of the present invention.

FIG. 6 is a graph of amplitude versus frequency for a metamaterial building block of the present invention.

FIG. 7 is a graph of phase versus frequency for a metamaterial building block of the present invention.

Fig. 8 is a graph of return loss versus frequency for a specific embodiment of the present invention.

Figure 9 is a normalized pattern of the main polarization at 8GHz for a specific embodiment of the present invention.

Fig. 10 is a normalized pattern of main polarization at 9GHz in accordance with an embodiment of the present invention.

Fig. 11 is a normalized pattern of main polarization at 10GHz in accordance with an embodiment of the present invention.

Fig. 12 is a normalized pattern of main polarization at 11GHz in accordance with a specific embodiment of the present invention.

Fig. 13 is a graph of actual gain versus frequency for an embodiment of the present invention.

The device comprises an 11-SMA connector, a 12-rectangular waveguide, a 13-cavity waveguide, a 131-long gap, a 21-matching metal patch, a 22-matching medium substrate, a 23-matching metal ground, a 31-metamaterial unit, a 311-first unit, a 312-second unit, a 313-third unit, a 32-medium substrate, a 33-metal ground and a 4-transition section.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Referring to fig. 1 to 5, the utility model provides a metamaterial antenna fed by a rectangular cavity, which includes a feed network, a matching section, a phase gradient super surface and a transition section 4, wherein the matching section, the phase gradient super surface and the transition section 4 are sequentially arranged on the feed network;

the feed network comprises an SMA connector 11, a rectangular waveguide 12 and a cavity waveguide 13, the cavity waveguide 13 is fixedly connected with the rectangular waveguide 12 and is positioned on the side of the rectangular waveguide 12, the SMA connector 11 is fixedly connected with the rectangular waveguide 12 and is positioned above the rectangular waveguide 12, and a probe of the SMA connector 11 penetrates through the upper wall of the rectangular waveguide 12.

A through long gap 131 is formed in the lateral side of the cavity waveguide 13, the matching section and the phase gradient super-surface are embedded in the long gap 131, and the central lines of the cavity waveguide 13, the matching section and the phase gradient super-surface are overlapped.

The matching section comprises a matching metal patch 21, a matching medium substrate 22 and a matching metal ground 23, the matching metal patch 21 is fixedly connected with the matching medium substrate 22 and is positioned on the upper surface of the matching medium substrate 22, and the matching metal ground 23 is arranged on the lower surface of the matching medium substrate 22.

The phase gradient super-surface comprises a plurality of super-material units 31, a medium substrate 32 and a metal ground 33, wherein each super-material unit 31 is arranged on the upper surface of the medium substrate 32, and the metal ground 33 is fixedly connected with the medium substrate 32 and is positioned on the lower surface of the medium substrate 32.

The metamaterial units 31 are arranged periodically, the distance between every two adjacent metamaterial units 31 is 10mm, and each metamaterial unit 31 is composed of a first unit 311, a second unit 312 and a third unit 313.

The transition section 4 is fixedly connected with the phase gradient super surface and is positioned on one side of the phase gradient super surface, which is far away from the matching section.

The width of the transition section 4 corresponds to the width of the rectangular waveguide 12.

The matching dielectric substrate 22, the dielectric substrate 32 and the transition section 4 have the same thickness dimension.

The radius of the probe of the SMA connector 11 is 0.62mm, the radius of the coaxial shell is 2.03mm, and the length of the coaxial probe is 6.5 mm.

The utility model also provides a specific embodiment, the rectangular waveguide 12 adopts the size design of the standard BJ100, and can just cover the required frequency band, and the length is 28.2 mm. The cavity waveguide 13 is formed by opening a through long slit 131 on the lower surfaces of both sides of a BJ100 rectangular waveguide. The rectangular waveguide used has the same width and height as the rectangular waveguide 12, and has a length of 202.5mm, and the long slot 131 has a length of 201.5mm, a width of 1mm, and a height of 5.2 mm. The size of the long gap 131 has a significant effect on the efficiency of exciting the metamaterial unit 31, and the determined dimension is optimal. The cavity waveguide 13 is fixedly connected with the rectangular waveguide, electromagnetic energy is fed into the rectangular waveguide 12 through the SMA connector 11, then is transmitted to the cavity waveguide 13 through the rectangular waveguide 12, and finally the metamaterial unit 31 is excited through the long gap 131.

The two matching metal patches 21 are symmetrically distributed on two sides of the central axis of the cavity waveguide 13, and have the length of 15mm and the width of 10 mm. The two matching metal patches 21 are respectively attached to two sides of the upper surface of the matching medium substrate 22, and the matching medium substrate 22 is 15mm long and 43mm wide. The matching metal ground 23 is attached to the lower surface of the matching medium substrate 22, and has the same size as the matching medium substrate 22, and the matching metal ground, the matching medium substrate 22 and the matching medium substrate form the matching section, and the matching section has the functions of reducing reflection generated when electromagnetic waves reach the interface between the rectangular waveguide 12 and the cavity waveguide 13, improving impedance matching, and transmitting as much energy as possible into the cavity waveguide 13.

The phase gradient metamaterial unit 31 is arranged on the phase gradient metamaterial surface, the distance between the metamaterial units 31 is 10mm, the 72 metamaterial units 31 are evenly divided into two groups, each group is 36, the two groups of metamaterial units 31 are symmetrically distributed on two sides of the central axis of the cavity waveguide 13, and the distance between the two groups of metamaterial units 31 is 23 mm. The two groups of metamaterial units 31 are symmetrically attached to two sides of the upper surface of the dielectric substrate 32, and the dielectric substrate 32 is 180mm long and 63mm wide. The metal ground 33 is attached to the lower surface of the dielectric substrate 32 and has the same size as the dielectric substrate 32.

Further, the phase gradient direction of the phase gradient super-surface of the antenna in this embodiment is horizontal to the right, which is opposite to the direction of energy flow in the cavity waveguide 13. If the phase difference between the metamaterial units 31 is changed, the angle of the antenna radiation pattern beam shift is changed. In the embodiment, the beam direction of the antenna at 9GHz is vertical and upward, and due to the arrangement of the symmetrical metamaterial units 31 on two sides, a radiation pattern generates double beams.

Referring to FIGS. 6 and 7, cross-polarized reflection amplitudes and phases are plotted as a function of frequency for three different sized units of metamaterial unit 31 over a frequency range of 7GHz to 11GHz, respectively. As can be seen from the figure, changing the size of the resonant ring opening of the metamaterial unit 31 and the rotation angle of the metamaterial unit 31 change the phase characteristics, and the phase change of the three units is kept stable and is about 2 pi/3. But the amplitude of the metamaterial unit 31 does not change much, and the amplitudes of the three units are almost always larger than 0.8 in the whole frequency band.

FIG. 8 is a graph of reflection coefficient with frequency variation in a frequency range from 7GHz to 11GHz of an embodiment of a metamaterial antenna fed by a quasi-rectangular cavity provided by the utility model. It can be seen that the impedance bandwidth of the antenna in this embodiment is 7.3GHz to 10.8GHz, and the relative bandwidth is about 38.7%.

Fig. 9 to 12 show the main polarization patterns and the actual gains of the present embodiment at four frequencies of 8GHz, 9GHz, 10GHz, and 11GHz, respectively. The included angles between the main polarization directions of different frequencies and the xoy plane are different, the included angle between the main polarization direction of the different frequencies and the xoy plane is 6 degrees at 8GHz, the included angle between the main polarization direction of the different frequencies and the xoy plane is-4.5 degrees at 9GHz, and the included angles between the main polarization direction of the different frequencies and the xoy plane are respectively-10.5 degrees and-13.5 degrees at 10GHz and 11 GHz. It can be seen from the figure that the antenna in this embodiment well achieves dual beams within the impedance bandwidth.

FIG. 13 is a graph showing the actual gain of the metamaterial antenna with rectangular-like cavity feeding varying with frequency in the frequency range of 8 GHz-11 GHz. It can be seen from the figure that the antenna in this embodiment has the maximum practical gain at 9GHz, which reaches 15.9 dBi.

The feed network is an improved structure of a rectangular waveguide resonant cavity, electromagnetic energy is radiated mainly through long gaps 131 on two sides of a cavity waveguide 13, by utilizing the characteristic, phase gradient super-surfaces are arranged at the long gaps 131 on the two sides, the phase gradient super-surfaces are excited through radiated energy, and then the direction of phase gradient is set to be opposite to the direction of energy radiation through the principle of super-surface unit radiation, so that the phase gradient super-surfaces radiate energy to a free space. The direction and the size of the phase gradient can influence the radiation direction of the phase gradient super-surface energy, so that the angle of the wave beam can be controlled at will by adjusting the arrangement of the super-surface units.

While the utility model has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the utility model.

Claims (9)

1. A metamaterial antenna with rectangular cavity-like feed is characterized in that,

the phase gradient super-surface feed circuit comprises a feed network, a matching section, a phase gradient super-surface and a transition section, wherein the matching section, the phase gradient super-surface and the transition section are sequentially arranged on the feed network;

the feed network comprises an SMA connector, a rectangular waveguide and a cavity waveguide, the cavity waveguide is fixedly connected with the rectangular waveguide and is positioned on the side of the rectangular waveguide, the SMA connector is fixedly connected with the rectangular waveguide and is positioned above the rectangular waveguide, and a probe of the SMA connector penetrates through the upper wall of the rectangular waveguide.

2. The rectangular-like cavity fed metamaterial structure antenna of claim 1,

the cavity waveguide is characterized in that a through long gap is formed in the side of the cavity waveguide, the matching section and the phase gradient super-surface are embedded in the long gap, and the central lines of the cavity waveguide, the matching section and the phase gradient super-surface are overlapped.

3. The rectangular-like cavity fed metamaterial structure antenna of claim 2,

the matching section comprises a matching metal patch, a matching medium substrate and a matching metal ground, the matching metal patch is fixedly connected with the matching medium substrate and is positioned on the upper surface of the matching medium substrate, and the matching metal ground is arranged on the lower surface of the matching medium substrate.

4. The rectangular-like cavity fed metamaterial structure antenna of claim 3,

the phase gradient super surface comprises a plurality of super material units, a medium substrate and a metal ground, wherein each super material unit is arranged on the upper surface of the medium substrate, and the metal ground is fixedly connected with the medium substrate and is positioned on the lower surface of the medium substrate.

5. The rectangular-like cavity fed metamaterial structure antenna of claim 4,

the metamaterial units are arranged periodically, the distance between every two adjacent metamaterial units is 10mm, and each metamaterial unit consists of a first unit, a second unit and a third unit.

6. The rectangular-like cavity fed metamaterial structure antenna of claim 5,

the transition section is fixedly connected with the phase gradient super surface and is positioned on one side of the phase gradient super surface, which is far away from the matching section.

7. The rectangular-like cavity fed metamaterial structure antenna of claim 6,

the width of the transition section is consistent with the width of the rectangular waveguide.

8. The rectangular-like cavity fed metamaterial structure antenna of claim 7,

the matching dielectric substrate, the dielectric substrate and the transition section are the same in thickness dimension.

9. The rectangular-like cavity fed metamaterial structure antenna of claim 8,

the radius of the probe of the SMA connector is 0.62mm, the radius of the coaxial shell is 2.03mm, and the length of the coaxial probe is 6.5 mm.

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