CN211858891U

CN211858891U - Flexible single stop band UWB-MIMO antenna based on coplanar waveguide feed

Info

Publication number: CN211858891U
Application number: CN202020812962.8U
Authority: CN
Inventors: 杜成珠; 靳高雅; 赵卓琳; 郑炜晴; 徐家铭; 李凯佳
Original assignee: Shanghai University of Electric Power
Current assignee: Shanghai University of Electric Power
Priority date: 2020-05-15
Filing date: 2020-05-15
Publication date: 2020-11-03
Anticipated expiration: 2030-05-15

Abstract

The utility model belongs to the antenna field, concretely relates to flexible single stop band UWB-MIMO antenna based on coplane waveguide feed has such characteristic, include: the substrate is rectangular; the two antenna units are positioned on the upper surface of the substrate and are respectively provided with a circular radiation patch, a gradually-changed trapezoidal microstrip line, a first grounding plate and a second grounding plate, the microstrip line is connected to the circular radiation patch, the two microstrip lines are respectively and vertically connected with a first side line and a second side line which are adjacent to the substrate, and the first grounding plate and the second grounding plate are respectively arranged on two sides of the microstrip line and are connected with the side lines of the substrate; and the isolation branch is arranged between the two antenna units, wherein one side of the circular radiation patch, which is far away from the microstrip line, is provided with a sector cutting angle, a sector groove with the length of 1/4 stop band frequency wavelength is also arranged on the circular radiation patch, the area of the first grounding plate is larger than that of the second grounding plate, and the isolation branch is in an inverted F shape.

Description

Flexible single stop band UWB-MIMO antenna based on coplanar waveguide feed

Technical Field

The utility model belongs to the antenna field, concretely relates to flexible single stop band UWB-MIMO antenna based on coplane waveguide feed.

Background

3.1-10.6GHz is officially classified into civil ultra-wideband by FCC in 2002, the ultra-wideband is greatly developed, and an ultra-wideband antenna is also developed. Because the ultra-wideband communication has the characteristics of high transmission rate, strong penetration capability, strong anti-interference capability and the like, the ultra-wideband antenna has numerous applications in the aspects of short-distance wireless communication, mobile communication, medical imaging, ground penetrating radar and the like at present. When wireless communication is performed, the surrounding environment is relatively complex, and therefore, when electromagnetic waves propagate, they encounter obstacles to generate direct radiation, refraction or reflection, which results in multipath fading. Multipath fading is a negative factor affecting communications, and MIMO (Multiple-input Multiple-output) technology developed later can improve this disadvantage. Especially in the current times when massive data needs to be transmitted, one of the currently popular 5G core technologies is the multi-channel MIMO technology. Combining ultra-wideband technology with MIMO antennas is therefore a good choice for the development of future wireless communications. However, with the increase of the number of antenna elements, the coupling effect between the antenna elements is not negligible. How to reduce the coupling of antenna units while ensuring the miniaturization of antennas becomes a difficult point in the design of MIMO antennas.

The 3.1GHz-10.6GHz is the application frequency band of the ultra-wideband communication, and the frequency band range also has various other communication systems, such as the wireless local area network, the china 5G frequency band released by the ministry of industry and telecommunications, the global microwave interconnection access, the satellite communication, the missile-borne system, and the like. In order to avoid the ultra-wideband antenna interfering with these known communication systems, a filtering device may be additionally designed at the front end of the communication system, but this occupies a large space, is not favorable for integration, and is not economical. The stop band characteristic of the antenna at the corresponding frequency band is simply and easily generated by etching different notch units on the structure of the antenna. Therefore, UWB-MIMO antennas having stop band characteristics become one of the focuses of researchers at present.

SUMMERY OF THE UTILITY MODEL

The present invention has been made to solve the above problems, and an object of the present invention is to provide a flexible single stop band UWB-MIMO antenna based on coplanar waveguide feed.

The utility model provides a flexible single stop band UWB-MIMO antenna based on coplane waveguide feed has such characteristic, include: the substrate is rectangular; the two antenna units are positioned on the upper surface of the substrate and are respectively provided with a circular radiation patch, a gradually-changed trapezoidal microstrip line, a first grounding plate and a second grounding plate, the microstrip line is connected to the circular radiation patch, the two microstrip lines are respectively and vertically connected with a first side line and a second side line which are adjacent to the substrate, and the first grounding plate and the second grounding plate are respectively arranged on two sides of the microstrip line and are connected with the side lines of the substrate; and the isolation branch is arranged between the two antenna units, wherein one side of the circular radiation patch, which is far away from the microstrip line, is provided with a sector cutting angle, a sector groove with the length of 1/4 stop band frequency wavelength is also arranged on the circular radiation patch, the area of the first grounding plate is larger than that of the second grounding plate, and the isolation branch is in an inverted F shape.

The utility model provides an in the flexible single stop band UWB-MIMO antenna based on coplane waveguide feed, can also have such characteristic: wherein, the size of fan-shaped corner cut does: the arc length is 3/10 of the perimeter of the circular radiating patch and the arc angle is 159 °.

The utility model provides an in the flexible single stop band UWB-MIMO antenna based on coplane waveguide feed, can also have such characteristic: wherein the distance between the two antenna units is 2.5 mm.

The utility model provides an in the flexible single stop band UWB-MIMO antenna based on coplane waveguide feed, can also have such characteristic: wherein the sector groove is concentric with the circular radiation patch and faces to the sector tangent angle, the radius of the sector groove is 7/10 of the radius of the circular radiation patch, and the arc angle is 290 degrees.

The utility model provides an in the flexible single stop band UWB-MIMO antenna based on coplane waveguide feed, can also have such characteristic: the flexible single-stop band UWB-MIMO antenna based on coplanar waveguide feed is used for isolating an ultra-wideband frequency band of WiMAX-3.5 GHz.

The utility model provides an in the flexible single stop band UWB-MIMO antenna based on coplane waveguide feed, can also have such characteristic: wherein the isolation branch is connected with the first edge line and faces the second edge line, or the isolation branch is connected with the second edge line and faces the first edge line.

The utility model provides an in the flexible single stop band UWB-MIMO antenna based on coplane waveguide feed, can also have such characteristic: the first ground plate and the second ground plate are both rectangular, a first ground plate gap is formed between the first ground plate and the microstrip line, a second ground plate gap is formed between the second ground plate and the microstrip line, and the first ground plate gap and the second ground plate gap are the same in size.

The utility model provides an in the flexible single stop band UWB-MIMO antenna based on coplane waveguide feed, can also have such characteristic: wherein, the substrate is a liquid crystal polymer and the thickness of the substrate is 0.1 mm.

The utility model provides an in the flexible single stop band UWB-MIMO antenna based on coplane waveguide feed, can also have such characteristic: the microstrip line adopts a coplanar waveguide feed structure.

Action and effect of the utility model

According to the utility model relates to a flexible single stop band UWB-MIMO antenna based on coplanar waveguide feed, because including two antenna element, every antenna element all has circular radiation paster, trapezoidal microstrip line of gradual change, first ground plate and second ground plate, and the circular radiation paster keeps away from one side of microstrip line and has the fan-shaped corner cut for the antenna can realize the miniaturization when guaranteeing the working bandwidth; the circular radiation patch is provided with a fan-shaped groove with the length of 1/4 stop band frequency wavelength, so that the antenna can isolate the frequency band of WiMAX-3.5 GHz; the area of the first grounding plate is larger than that of the second grounding plate, so that the working width of the antenna can be expanded due to the asymmetrical structure; a MIMO structure with two antenna units can generate a plurality of transmission paths, thereby greatly reducing the influence of multipath fading, and the coupling current between the two antenna units can be effectively reduced by arranging the inverted F-shaped isolation branch between the two antenna units. Therefore, the utility model discloses a UWB-MIMO antenna can guarantee the miniaturization, can reduce the coupling between the antenna element again to can also effectively keep apart WiMAX-3.5GHz frequency channel under the condition that satisfies the ultra wide band.

Drawings

Fig. 1 is a schematic structural diagram of a flexible single-stop-band UWB-MIMO antenna based on coplanar waveguide feeding according to an embodiment of the present invention;

fig. 2 is the S of the flexible single stop band UWB-MIMO antenna based on coplanar waveguide feeding in the embodiment of the present invention₁₁A simulation result graph;

fig. 3 is a diagram illustrating the simulation result of the isolation of the flexible single-stop-band UWB-MIMO antenna based on coplanar waveguide feeding according to the embodiment of the present invention.

Detailed Description

In order to make the technical means, creation features, achievement purpose and efficacy of the present invention easy to understand, the following embodiments are specifically illustrated with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a flexible single-stop-band UWB-MIMO antenna based on coplanar waveguide feeding according to an embodiment of the present invention.

As shown in fig. 1, the flexible single stop band UWB-MIMO antenna 100 based on coplanar waveguide feeding of the present embodiment includes a substrate 10, a first antenna element 20, a second antenna element 30, and an isolation branch 40.

The substrate 10 is rectangular and has a first border line 11 and a second border line 12 adjacent to each other. The substrate 10 is a liquid crystal polymer and has a thickness of 0.1 mm.

The first antenna element 20 and the second antenna element 30 are both located on the upper surface of the substrate. In the present embodiment, the first antenna element 20 and the second antenna element 30 are placed on the upper surface of the substrate 10.

The first antenna element 20 comprises a circular radiating patch 21, a tapered trapezoidal microstrip line 22, a first ground plate 23 and a second ground plate 24.

The circular radiation patch 21 and the microstrip line 22 are connected together, and the microstrip line 22 is connected perpendicularly to the first side line 11. The side of the circular radiating patch 21 remote from the microstrip line 22 has a scalloped corner 211. The size of the scallop 211 is: the arc length is 3/10 of the perimeter of the circular radiating patch and the arc angle is 159 °. The design of the sector cut angle 211 is to achieve miniaturization and ultra-wideband of the antenna, and specifically, by analyzing the current distribution on the radiating patch, the surface current is mainly concentrated on the bottom edge near the feed point and the current density of the upper half is small. Therefore, as a starting point, the upper half part of the circular patch is cut off, and the corner-cut circular radiation patch is provided, so that the miniaturization is realized and the working bandwidth is ensured.

The circular radiation patch 21 is further provided with a sector groove 212 having a length of 1/4 stop band frequency wavelengths, the sector groove 212 is concentric with the circular radiation patch 21 and faces the sector cut angle 211, the radius of the sector groove 212 is 7/10 of the radius of the circular radiation patch 21, and the arc angle is 290 °. The fan-shaped slot 212 is formed by slotting the circular radiation patch 21 by using a slotting technology.

The microstrip line 22 adopts a coplanar waveguide feed structure and adopts a gradual change structure in the design of the microstrip line, thereby further expanding the working bandwidth of the antenna.

The first ground plate 23 and the second ground plate 24 are respectively disposed on both sides of the microstrip line 22, and are connected to the first side line 11. The first ground plate 23 and the second ground plate 24 are both rectangular, and the area of the first ground plate 23 is larger than that of the second ground plate 24. A first ground plate gap is formed between the first ground plate 23 and the microstrip line 22, and a second ground plate gap is formed between the second ground plate 23 and the microstrip line 22. The first floor gap and the second floor gap are the same size. That is, the length of the first ground plate 23 is greater than the length of the second ground plate 24 in the extending direction of the first border 11, and the length of the first ground plate 23 is equal to the length of the second ground plate 24 in the extending direction of the second border 12.

The second antenna unit 30 has a structure similar to that of the first antenna unit 20, and also includes a circular radiation patch, a gradually-changing trapezoidal microstrip line, a first ground plate, and a second ground plate. The difference lies in that: the microstrip line of the second antenna unit 30 is vertically connected to the second edge line 12; the first ground plane and the second ground plane of the second antenna element 30 are connected to the second edge line 12. The rest structures are completely the same.

The first antenna element 20 and the second antenna element 30 are vertically arranged to form a binary ultra-wideband MIMO antenna. At this time, the coupling between the first antenna element 20 and the second antenna element 30 is severe, and further measures are required to reduce the coupling between the antennas. In the embodiment, the relative position between the two antenna units is adjusted, and the inverted-F-shaped isolation branch 40 is added between the two antenna units, so that the coupled current between the two antenna units is reduced, and the isolation of the antenna is lower than-20 dB. In this embodiment, the first antenna unit 20 and the second antenna unit 30 are perpendicular to each other, the distance is 2.5mm, and the second antenna unit 30 is adjusted upward by 2.5 mm.

The isolation stub 40, which is an inverted F-shape, is disposed between the first antenna element 20 and the second antenna element 30. The isolation branch 40 includes a first branch 41, a second branch 42, and a third branch 43. The first branch 41 is connected perpendicularly to the first edge line 33. The second branch 42 and the third branch 43 are both vertically connected to the first branch 41 and are both located on a side of the first branch 41 close to the second antenna unit 30, wherein the second branch 42 is connected to the first edge 33. I.e. the spacer branch 40 is directed towards the second edge line 12. The length of the first branch 41 is 12mm, and the length of the second branch 42 is smaller than that of the third branch 43. In the present embodiment, the lengths of the second and

third branches

42 and 43 are 3mm and 4mm, respectively. The widths of the first, second and

third branches

41, 42, 43 are all 1 mm.

Fig. 2 is the S of the flexible single stop band UWB-MIMO antenna based on coplanar waveguide feeding in the embodiment of the present invention₁₁A simulation result graph; fig. 3 is a diagram illustrating the simulation result of the isolation of the flexible single-stop-band UWB-MIMO antenna based on coplanar waveguide feeding according to the embodiment of the present invention.

The flexible single stop band UWB-MIMO antenna 100 based on coplanar waveguide feed of the embodiment is subjected to S₁₁The results of the simulation experiment and the isolation simulation experiment are shown in fig. 2 and 3, respectively. It can be seen from fig. 2 that the UWB-MIMO antenna 100 of the present embodiment can well block frequency band interference of WiMAX-3.5GHz and WLAN (5.725-5.825GHz) under the requirement of ultra wide band. Fig. 3 shows that the isolation of the UWB-MIMO antenna 100 of the present embodiment in the operating frequency band is substantially lower than-20 dB, and meets the requirement for isolation.

Effects and effects of the embodiments

According to the flexible single-stop-band UWB-MIMO antenna based on coplanar waveguide feed, the antenna comprises two antenna units, each antenna unit is provided with a circular radiation patch, a gradually-changed trapezoidal microstrip line, a first ground plate and a second ground plate, and one side of the circular radiation patch, which is far away from the microstrip line, is provided with a sector cut angle, so that the antenna can be miniaturized while the working bandwidth is ensured; the circular radiation patch is provided with a fan-shaped groove with the length of 1/4 stop band frequency wavelength, so that the antenna can isolate the frequency band of WiMAX-3.5 GHz; the area of the first grounding plate is larger than that of the second grounding plate, so that the working width of the antenna can be expanded due to the asymmetrical structure; the two vertical antenna units are adopted to form a binary ultra-wideband MIMO structure, multiple transmission paths can be generated, the influence of multipath fading is greatly reduced, and the coupling current between the two antenna units can be effectively reduced by arranging the inverted-F-shaped isolation branch between the two antenna units. Therefore, the utility model discloses a UWB-MIMO antenna can guarantee the miniaturization, can reduce the coupling between the antenna element again to can also effectively keep apart WiMAX-3.5GHz frequency channel under the condition that satisfies the ultra wide band.

Furthermore, the substrate is a Liquid Crystal Polymer (LCP), the thickness of the substrate is 0.1mm, and the novel high-performance special engineering plastic developed in the early 80 s has the advantages of excellent thermal stability, heat resistance, chemical resistance, electric insulation performance, low thermal expansion coefficient, low cost, small loss, ultra-thin property and the like, so that the UWB-MIMO antenna has more stable performance. In addition, the LCP material also has excellent flexibility, can cover the surface of a human body and meets the requirements of wearable antennas.

Furthermore, the microstrip line adopts a coplanar waveguide feed structure, the coplanar waveguide feed has the advantages of low loss, low cost, low dispersion, easy connection with various microwave components and parts and the like, and due to the unique planar structure, the UWB-MIMO antenna has the advantages of wide frequency band, easy processing, only need of a single metal layer and the like.

Furthermore, the UWB-MIMO antenna of the embodiment can isolate the frequency band of WiMAX-3.5GHz while meeting the ultra-wideband through simulation test, the performance meets the requirements, and the UWB-MIMO antenna has great research and application prospects.

The above embodiments are preferred examples of the present invention, and are not intended to limit the scope of the present invention.

Claims

1. A flexible single stop band UWB-MIMO antenna based on coplanar waveguide feed, characterized by, includes:

the substrate is rectangular;

two antenna units located on the upper surface of the substrate and each having a circular radiation patch, a gradually-changing trapezoidal microstrip line, a first ground plate and a second ground plate,

the microstrip lines are connected on the circular radiation patch, and the two microstrip lines are respectively and vertically connected with the adjacent first side line and the second side line of the substrate,

the first grounding plate and the second grounding plate are respectively arranged on two sides of the microstrip line and are connected with the side line of the substrate; and

an isolation stub disposed between the two antenna units,

wherein, one side of the circular radiation patch far away from the microstrip line is provided with a fan-shaped cutting angle, and the circular radiation patch is also provided with a fan-shaped groove with the length of 1/4 stop band frequency wavelength,

the first ground plate has a larger area than the second ground plate,

the isolation branch is in an inverted F shape.

2. The flexible single stop-band UWB-MIMO antenna based on coplanar waveguide feed of claim 1, wherein:

wherein the size of the fan-shaped cutting angle is as follows: the arc length is 3/10 of the perimeter of the circular radiating patch and the arc angle is 159 °.

3. The flexible single stop-band UWB-MIMO antenna based on coplanar waveguide feed of claim 1, wherein:

wherein the distance between the two antenna units is 2.5 mm.

4. The flexible single stop-band UWB-MIMO antenna based on coplanar waveguide feed of claim 1, wherein:

wherein the sector-shaped groove is concentric with the circular radiation patch and faces the sector-shaped tangent angle, the radius of the sector-shaped groove is 7/10 of the radius of the circular radiation patch, and the arc angle is 290 degrees.

5. The flexible single stop-band UWB-MIMO antenna based on coplanar waveguide feed of claim 4, characterized in that:

the flexible single-stop-band UWB-MIMO antenna based on coplanar waveguide feed is used for isolating an ultra-wideband frequency band of WiMAX-3.5 GHz.

6. The flexible single stop-band UWB-MIMO antenna based on coplanar waveguide feed of claim 1, wherein:

wherein the isolation branch is connected with the first edge line and faces the second edge line, or the isolation branch is connected with the second edge line and faces the first edge line.

7. The flexible single stop-band UWB-MIMO antenna based on coplanar waveguide feed of claim 1, wherein:

the first ground plate and the second ground plate are both rectangular, a first ground plate gap is formed between the first ground plate and the microstrip line, a second ground plate gap is formed between the second ground plate and the microstrip line, and the first ground plate gap and the second ground plate gap are the same in size.

8. The flexible single stop-band UWB-MIMO antenna based on coplanar waveguide feed of claim 1, wherein:

wherein, the substrate is a liquid crystal polymer, and the thickness of the substrate is 0.1 mm.

9. The flexible single stop-band UWB-MIMO antenna based on coplanar waveguide feed of claim 1, wherein:

the microstrip line adopts a coplanar waveguide feed structure.