KR20130025134A - Dual-band omnidirectional circularly polarized wave antenna using metamaterial - Google Patents

Abstract

PURPOSE: A dual band omnidirectional circularly polarized antenna is provided to implement a strong horizontal polarization by forming a branch patch on the upper side and the lower side of a substrate to use a ground plate. CONSTITUTION: A substrate(100) has a dielectric planar structure. A first patch(110) of a mushroom structure is formed on a first plane of the substrate. A second patch(120) of the mushroom structure is formed on a second plane of the substrate. The first patch and the second patch have a bent branch type on the outside of a circular patch. The first patch and the second patch are connected through one or more vias(130).

Description

DUAL-BAND OMNIDIRECTIONAL CIRCULARLY POLARIZED WAVE ANTENNA USING METAMATERIAL}

The present invention relates to an omnidirectional circular polarization antenna, and more particularly to an antenna having a dual band circular polarization.

For many people in modern times, portable digital communication devices have become an essential element. Consumers want to be provided with various high quality services they want anytime and anywhere. In addition, portability, design, and various functions are very important factors in the selection of portable digital communication devices for consumers. Therefore, the portable digital communication device should have no configuration of additional peripheral devices and should have various functions while having a small size. However, in implementing a wireless communication device, the efficiency of the antenna is a limitation because it depends on the physical size. In general, the antenna should be mounted inside the communication device, and the antenna must be faithfully satisfied with the complex radio wave transmission and reception role only when the surrounding interference is minimal.

Recently, research has been conducted on a technique for artificially creating a material having a new electromagnetic property, which does not exist naturally, metamaterial. In the field of antennas, the use of new electromagnetic properties of Left-Handed Metamaterial (LHM), a material with both negative permittivity and per-meability at the same time, is used to develop small antennas that are not constrained by physical size. Studies are being actively conducted. Among them, research using a special resonance characteristic called zero-order resonator (ZOR) using metamaterial technique has been attracting attention. It is possible to further adjust this value by further implementing series capacitance and parallel inductance in the line or circuit carrying the signal so that the resonant frequency can be determined irrespective of the physical size of the transmission line.

In particular, in the omnidirectional circular polarization antenna, the omnidirectional and circular polarization characteristics are very useful for GPS, satellite communication, personal portable terminal, etc. because they do not require alignment between antennas. Conventional omnidirectional circularly polarized antennas are designed by designing two linear antennas to have a phase difference of 90 degrees, or by arranging antennas having one circularly polarized characteristic in an array so that circularly polarized waves appear in all directions. However, these conventional omni-directional circularly polarized antennas have a relatively large electrical size and are not planar antennas, so there is a problem in actual use in a communication system.

The technical problem to be achieved by the present invention is to solve the conventional problems, to provide an antenna having a dual band omni-directional circular polarization characteristics as a small planar form.

The metamaterial dual band omnidirectional circularly polarized antenna according to an embodiment of the present invention includes a substrate having a flat plate structure of a dielectric component, a first patch of a mushroom structure formed on a first plane of the substrate, and a second of the substrate. Including a second patch of mushroom structure formed on the plane, wherein the first patch, the second patch is attached to one or more branch patches having a branch shape bent to the outer portion of the circular patch.

In addition, the first patch and the second patch may be connected through one or more vias.

In addition, a single feed point for feeding power to either the first patch or the second patch may be formed.

In addition, any one of the first patch or the second patch may be a ground plate of the antenna.

In addition, the circular patch may cause vertical polarization to be generated with respect to the ground plane, and the branch patch may cause horizontal polarization with respect to the ground plane.

In addition, the branch patch may be formed in a clockwise or counterclockwise direction with respect to the circular patch.

The branch patch of the first patch and the branch patch of the second patch may be formed in opposite directions.

In addition, the branch patch of the first patch and the branch patch of the second patch may be formed in a region facing each other but not overlapping with respect to the substrate.

In addition, the horizontal and vertical polarization components of the antenna may vary according to the length and width of the branch patch.

In the embodiment of the present invention, the circular mushroom structure zero order resonance was used to obtain the dual band omnidirectional radiation pattern and the vertical polarization, and the branch patch bent to the circular patch was formed to obtain the horizontal polarization. A patch having branch patches was formed on and below the substrate to use one as a ground plate, and branch patches of each patch were formed in opposite directions. Accordingly, the antenna according to the embodiment of the present invention has an omnidirectional circular polarization characteristic and can obtain a stronger horizontal polarization than a conventional omnidirectional antenna. In addition, a dual band omnidirectional circular polarization can be obtained.

1 is a perspective view of a metamaterial dual band omnidirectional circular polarization antenna according to an embodiment of the present invention;
2A and 2B are a plan view and a cross-sectional view of the metamaterial dual band omnidirectional circular polarization antenna according to FIG. 1;
3 is an exemplary view for explaining the operation principle of the meta-material dual band omnidirectional circular polarization antenna according to FIG.
4 is an exemplary diagram for describing the S-parameters in the zeroth order resonance mode and the first resonance mode of the metamaterial dual band omnidirectional circular polarization antenna according to FIG. 1;
5A and 5B are exemplary diagrams for explaining the magnitude ratio, phase difference, and axial ratio in the zero-order resonance mode and the first-order resonance mode of the metamaterial dual band omnidirectional circular polarization antenna according to FIG. 1;
6A and 6B are exemplary diagrams for describing radiation patterns in an XY plane and an XZ plane in a zero-order resonance mode and a first-order resonance mode of the metamaterial dual band omnidirectional circular polarization antenna according to FIG. 1.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of the functions in the embodiments, and the meaning of the terms may vary depending on the user, the intention or the precedent of the operator, and the like. Therefore, the meaning of the terms used in the following embodiments is defined according to the definition when specifically defined in this specification, and unless otherwise defined, it should be interpreted in a sense generally recognized by those skilled in the art.

1 is a perspective view of a metamaterial dual band omnidirectional circular polarization antenna according to an embodiment of the present invention.

Referring to FIG. 1, the metamaterial dual band omnidirectional circular polarization antenna includes a substrate 100, a first patch 110, and a second patch 120. The substrate 100 is a flat plate structure composed of a dielectric component, and the dielectric constant and thickness thereof are set differently according to user settings. For example, the substrate 100 may have a planar shape of a rectangle, a circle, and an oval, and the permittivity ε _r may be 2.2. In addition, a via hole and a feeding hole are formed in the substrate 100, and the via hole and the feeding hole penetrate the first plane and the second plane of the substrate 100. Here, the first plane and the second plane mean an upper surface or a lower surface of the substrate 100. The via hole is an area for receiving the via 130 connecting the first patch 110 and the second patch 120, and the feed hole supplies power to the first patch 110 or the second patch 120. It is an area for accommodating power lines for supplying. In this case, the feed hole accommodates the inner conductor of the coaxial cable, but does not accommodate the outer conductor, and the inner conductor contacts the feed point 140.

The first patch 110 is formed in a mushroom structure on the first plane of the substrate 100, it is also possible to form using a thin copper (Cu) plate, excellent electrical conduction, good formability and processability silver (Ag) Alternatively, metal thin plates such as aluminum (Al) may be used, but are not necessarily limited thereto. The first patch 110 is formed by attaching one or more branch patches 112 having branch shapes bent to the outer portion of the circular patch. In this case, the branch patch 112 bent direction may be set clockwise or counterclockwise.

The second patch 120 is formed in a mushroom structure on the second plane of the substrate 100, and is formed of a copper (Cu) thin plate, silver (Ag), or aluminum (Al) material such as the first patch 110. It is also possible to use, but is not necessarily limited thereto. The second patch 120 is formed by attaching one or more branch patches 122 having branch shapes bent to the outer portion of the circular patch. In this case, the bent direction of the branch patch 122 may be set clockwise or counterclockwise, but the branch patch 122 of the first patch 110 and the branch patch 122 of the second patch 120 may be It may be formed in opposite directions to each other. In addition, the branch patch 112 of the first patch 110 and the branch patch 122 of the second patch 120 may be formed in regions that face each other but do not overlap each other with respect to the substrate 100.

Meanwhile, in the present invention, either one of the first patch 110 or the second patch 120 serves as a ground plate of the antenna. In the present specification, for convenience of description, the second patch 120 has been described as a ground plate. Accordingly, the inner conductor of the coaxial cable passes through the substrate 100 and is connected to the feed point 140 of the first patch 110, and the outer conductor of the coaxial cable is the ground plate second patch 120. Is in contact with.

2A and 2B are a plan view and a cross-sectional view of the metamaterial dual band omnidirectional circular polarization antenna according to FIG. 1.

Referring to FIG. 2A, the first patch 110 and the second patch 120 face each other with the substrate 100 interposed therebetween, and the branch patch 112 and the second patch 120 of the first patch 110 face each other. Branch patches 122 are staggered from each other. In this case, the bent direction of the branch patch 112 of the first patch 110 and the bent direction of the branch patch 122 of the second patch 120 are opposite directions. For example, when the branch patch 112 of the first patch 110 is bent in the clockwise direction, the branch patch 122 of the second patch 120 is bent in a counterclockwise direction. This is to make the intensity of the horizontal polarization generated in the branch patches 112 and 122 stronger.

In addition, the central patch 111 of the first patch 110 is designed with a diameter D of 14 mm, the branch patch 112 of the first patch 110 has a branch length L of 20 mm, the width of the branch (W) is 1.5mm, the distance (S) between the central patch 111 and the branch patch 112 may be designed to 4mm. In this case, the central patch 121 of the second patch 120, which is a ground plate, may be designed to have a diameter of 18 mm that is equal to or larger than the central patch 111 of the first patch 110. The horizontal and vertical polarization components of the antenna may vary according to the length L and the width W of the branch patches 112 and 122.

Referring to FIG. 2B, via holes and through holes are formed in the substrate 100 to accommodate the vias 130 and the feed line, and a port 150 is formed in the second patch 120 to connect external coaxial cables. To facilitate. As shown in FIG. 2B, the first patch 110 and the second patch 120 may be connected through one or more vias 130, and may be fed to either the first patch 110 or the second patch 120. A single feed point 140 may be formed. When the second patch 120 is designed as a ground plate, the feed point 140 is formed in the first patch 110.

FIG. 3 is an exemplary diagram for describing an operation principle of a metamaterial dual band omnidirectional circular polarization antenna according to FIG. 1.

Referring to FIG. 3, in the circular patch portion of the first patch 110, vertical polarization is generated with respect to the second patch 120, which is a ground plate, and the branch patch 112 of the first patch 110 is a second patch. Horizontal polarization is generated for 120. Since the first patch 110 is formed in a circular mushroom structure, it forms an electric field perpendicular to the ground plane of the second patch 120, and this vertical electric field is due to the vertical polarization. In addition, in the zero-order resonant mode and the first-order resonant mode, the unit structure resonator itself provides a phase difference of 90 degrees between the vertical polarization and the horizontal polarization. This contributes to the generation of omnidirectional circular polarization.

In FIG. 3, since the three branch patches 112 of the first patch 110 are arranged in a clockwise direction, the radiation characteristic of the antenna has left polarization characteristics. If the branch patches 112 are arranged in the counterclockwise direction, the radiation characteristic of the antenna has a post wave characteristic. As described above, a plurality of branch patches 122 are formed in the central patch 121 of the second patch 120, and the direction of the branch patches 122 is in the direction of the branch patch 112 of the first patch 110. In contrast to the above, the branch patch 112 of the first patch 110 and the branch patch 122 of the second patch 120 may be formed in regions that face each other but do not overlap each other with respect to the substrate 100. . The first patch 110 receives electric power from the inner conductor of the coaxial cable through the feed point 140, and the branch patch 112 is formed with an electric field in a horizontal clockwise direction by the supplied electric power. In the case of 120, the electric field is formed in the same direction as the branch patch 122 of the first patch 110. Therefore, the branch patch 112 of the first patch 110 and the branch patch 122 of the second patch 120 may be in different directions to enhance the strength of the horizontal polarization.

FIG. 4 is an exemplary diagram for describing S-parameters in a zeroth order resonance mode and a first order resonance mode of the metamaterial dual band omnidirectional circular polarization antenna according to FIG. 1.

Referring to FIG. 4, the antenna of the present invention may operate in a zeroth order resonance mode and a first order resonance mode according to the supplied power. When the antenna operates in the 0th-order resonant mode, the antenna has a 10 dB bandwidth in the range of approximately 2.787 [GHz] to 2.807 [GHz], so 2.798 [GHz] becomes the center frequency. On the other hand, when the antenna operates in the first resonant mode, since the antenna has a 10 dB band width in the range of approximately 4.811 [GHz] to 4.922 [GHz], 4.865 [GHz] becomes the center frequency. Therefore, the antenna radiation characteristics of the dual band can be obtained by using one antenna.

5A and 5B are exemplary diagrams for explaining size ratios, phase differences, and axial ratios in the zero-order resonance mode and the first-order resonance mode of the metamaterial dual band omnidirectional circular polarization antenna according to FIG. 1.

5a and 5b, the central patch 111 of the first patch 110 has a diameter D of 14 mm, and the branch patch 112 of the first patch 110 has a branch length L. 20 mm, the width W of the branch is 1.5 mm, and the distance S between the central patch 111 and the branch patch 112 is designed to be 4 mm. FIG. 5A illustrates the pattern of the fray in the zero-order resonant mode, and Magnitude Ratio, Phase Difference, and Axial Ratio are measured as shown in the following table at the center frequency of 2.798 [GHz].

at least maximum Average Size ratio 0.813 0.889 0.848 Phase difference 87.89 ° 91.35 ° 89.75 ° Axial ratio 1.03 dB 1.80 dB 1.45 dB

5B shows a radiation pattern in the first resonance mode, and Magnitude Ratio, Phase Difference, and Axial Ratio are measured as shown in the following table at the center frequency of 4.865 [GHz]. do.

at least maximum Average Size ratio 0.960 0.990 0.978 Phase difference 72.48 ° 84.07 ° 78.22 ° Axial ratio 0.90 dB 2.72 dB 1.81 dB

6A and 6B are exemplary diagrams for explaining radiation patterns in the X-Y plane and the X-Z plane in the zero-order resonance mode and the first-order resonance mode of the metamaterial dual band omnidirectional circular polarization antenna according to FIG. 1.

Referring to FIG. 6A, the XY plane and the XZ plane show good characteristics because the difference between the left and right waves is 10 dB or more, and since the left side wave is stronger, it can be seen that the left side wave characteristic. Meanwhile, referring to FIG. 6B, both the XY plane and the XZ plane show good characteristics because the difference between the left and right waves is 10 dB or more, and since the post wave is stronger, it can be seen that it is a post wave characteristic.

In the embodiment of the present invention, a circular mushroom structure zero order resonator was used to obtain a dual band omnidirectional radiation pattern and vertical polarization, and branched patches 112 and 122 bent to circular patches were formed to obtain horizontal polarization. Patches having branch patches 112 and 122 formed on circular central patches 111 and 121 are formed above and below the substrate 100 to use one as a ground plate, and branch patches 112 and 122 of each patch. Formed in opposite directions to each other. Accordingly, the antenna according to the embodiment of the present invention has an omnidirectional circular polarization characteristic and can obtain a stronger horizontal polarization than a conventional omnidirectional antenna. In addition, a dual band omnidirectional circular polarization can be obtained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, Therefore, the present invention should be construed as a description of the claims which are intended to cover obvious variations that can be derived from the described embodiments.

100: substrate 110: first patch
111, 121: central patch 112, 122: eggplant patch
120: second patch 130: via
140: feed point 150: port

Claims (9)

A substrate having a planar structure of a dielectric component;
A first patch of mushroom structure formed on a first plane of the substrate;
Including a second patch of the mushroom structure formed on the second plane of the substrate,
The first patch and the second patch is a metamaterial dual band omnidirectional circular polarization antenna to which at least one branch patch having a branch shape bent at the outer portion of the circular patch is attached. The method of claim 1,
And the first patch and the second patch are connected through at least one via. The method of claim 1,
A metamaterial dual band omnidirectional circular polarization antenna having a single feed point for feeding power to either the first patch or the second patch. The method of claim 1,
Any one of the first patch or the second patch is a metamaterial dual band omnidirectional circular polarization antenna of the antenna. 5. The method of claim 4,
And wherein the circular patch causes vertical polarization to be generated with respect to the ground plane, and the branch patch causes horizontal polarization with respect to the ground plane. The method of claim 1,
Wherein said branch patch is formed in a clockwise or counterclockwise direction relative to said circular patch. The method according to claim 6,
The branch patch of the first patch and the branch patch of the second patch are metamaterial dual band omnidirectional circular polarization antennas formed in opposite directions. The method of claim 7, wherein
The branch patch of the first patch and the branch patch of the second patch are opposed to each other, the metamaterial dual band omnidirectional circular polarization antenna is formed in a region that does not overlap with respect to the substrate. The method of claim 5,
The metamaterial dual band omnidirectional circular polarization antenna of which the horizontal and vertical polarization components of the antenna vary according to the length and width of the branch patch.

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