CN213212368U

CN213212368U - Circularly polarized microstrip antenna

Info

Publication number: CN213212368U
Application number: CN202022438862.6U
Authority: CN
Inventors: 韩国栋; 杨国栋; 崔子卿; 高冲; 段永强; 刘扬
Original assignee: CETC 54 Research Institute
Current assignee: CETC 54 Research Institute
Priority date: 2020-10-28
Filing date: 2020-10-28
Publication date: 2021-05-14
Anticipated expiration: 2030-10-28

Abstract

The utility model discloses a circular polarization microstrip antenna belongs to microstrip antenna technical field. The feed network comprises a matching dielectric layer, a radiation dielectric layer and a feed network layer which are arranged in a stacking manner from top to bottom; the system also comprises a main feeding port and two feeding probes; the upper surface of the matching dielectric layer is provided with a microstrip patch unit group with a rectangular annular structure, a radiation patch is arranged between the matching dielectric layer and the radiation dielectric layer, and the radiation patch feeds power through two feed probes. The circularly polarized feed network is positioned in the middle of the feed network dielectric layer, and the total feed port is coaxial feed. The utility model discloses can be better satisfy circular polarized antenna independent utility or group battle array and use.

Description

Circularly polarized microstrip antenna

Technical Field

The utility model relates to microstrip antenna technical field, in particular to circular polarization microstrip antenna.

Background

The antennas currently used in communication systems have several forms, which are characterized in terms of performance, implementation method, etc., but have their own advantages and disadvantages.

1. The circularly polarized antenna in the microstrip form realizes circularly polarized signals in a mode of cutting corners of microstrip patches, and can realize the circularly polarized signals by single feed, but the circularly polarized axial ratio of the antenna is usually lower in efficiency due to the fact that the cutting corners of the patches bring smaller wide angular axial ratio, and has certain usability in some fields, but the microstrip patches are not beneficial to miniaturization, and meanwhile, the microstrip patch is not beneficial to realizing the axial ratio characteristic of wider wave beams.

2. The spiral circularly polarized antenna is very suitable for generating circularly polarized signals, has good wide-angle-axis ratio characteristic, and is simple in processing and implementation method, but the spiral antenna is high in height, so that the spiral circularly polarized antenna is not beneficial to realizing miniaturization.

3. The circularly polarized antenna in the waveguide form, which is generally implemented by machining, needs to add a partition phase shifter inside the waveguide to implement circular polarization, and needs to add a dielectric material inside the waveguide for miniaturization, which easily reduces the radiation efficiency of the antenna.

4. The circularly polarized antenna in the asymmetric oscillator form adopts unequal oscillator arms, and realizes circular polarization by introducing additional phase shift.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a circular polarization microstrip antenna, this antenna has high efficiency, low-power consumption to can be better be applicable to among single antenna or the group array antenna.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a circularly polarized microstrip antenna comprises a matching dielectric layer, a radiation dielectric layer and a feed network layer which are stacked from top to bottom; the system also comprises a main feeding port and two feeding probes;

the main body of the matching medium layer is a first medium plate, and the upper surface of the matching medium layer is provided with a micro-strip patch unit group; the main body of the radiation medium layer is a second medium plate, and a radiation patch is arranged between the first medium plate and the second medium plate; the feed network layer comprises two feed dielectric plates which are stacked from top to bottom, and a circular polarization feed network is arranged between the two feed dielectric plates; metal plates are arranged on the upper surface and the lower surface of the feed network layer, wherein two small holes for two feed probes to pass through are formed in the metal plate on the upper surface;

the two feed probes are connected to the lower surface of the radiation patch and are perpendicular to the lower surface of the radiation patch; the circularly polarized feed network comprises an equal-power-division circular-ring-shaped microstrip feed line and two unequal-length feed lines which are sequentially connected to the same end point of the equal-power-division circular-ring-shaped microstrip feed line, and the two unequal-length feed lines are parallel to each other; the tail ends of the two feed probes are respectively connected to two end points of the circularly polarized feed network; the main feed port is connected below the extension of the equal power division circular-ring-shaped microstrip feeder line, and a small hole for exposing the main feed port is formed in the metal plate on the lower surface of the feed network layer;

the phase difference between the two unequal-length feed lines is 90 degrees, and the feed line close to the annular microstrip feed line is shorter than the other feed line; the feed probe and the total feed port are not in contact with the metal plates on the upper surface and the lower surface of the feed network layer.

Furthermore, the microstrip patch unit group is a rectangular ring structure formed by a plurality of metamaterial microstrip patch units.

Furthermore, the radiation patch is positioned right below the microstrip patch unit group.

The utility model adopts the beneficial effect that above-mentioned technical scheme produced lies in:

1. the utility model discloses utilize circular polarization feed network to realize the circular polarization of antenna, improved wide angle axial ratio characteristic.

2. The utility model discloses an annular microstrip paster unit group of rectangle that metamaterial microstrip paster unit constitutes has improved antenna efficiency.

3. The utility model discloses have the beam width of broad, axial ratio characteristic, satisfy navigation antenna's operation requirement, antenna beam, standing-wave ratio and axial ratio have good performance.

4. The utility model discloses an entire structure can adopt multilayer printing board integration crimping shaping mode, and is simple feasible, can effectively reduce antenna cost.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is a schematic diagram of the feed network structure in fig. 1.

Fig. 3 is a standing-wave ratio simulation result according to an embodiment of the present invention.

Fig. 4 is a diagram simulation result according to an embodiment of the present invention.

Fig. 5 is an axial ratio simulation result according to an embodiment of the present invention.

In the figure: 1. the power-dividing circular microstrip feeder line 2, the metamaterial microstrip patch unit 3, the first dielectric plate, 5, the second dielectric plate, 6, the short microstrip line 7, the long microstrip line 8, the lower layer feed dielectric plate, 9, the upper layer feed dielectric plate, 10 and the extension.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and specific embodiments.

the two feed probes are connected to the lower surface of the radiation patch and are perpendicular to the lower surface of the radiation patch; the circularly polarized feed network comprises an equal-power-division circular-ring-shaped microstrip feed line and two unequal-length feed lines which are sequentially connected to the same end point of the equal-power-division circular-ring-shaped microstrip feed line, the two unequal-length feed lines comprise a long feed line and a short feed line, and the two feed lines are parallel to each other; the tail ends of the two feed probes are respectively connected to two end points of the circularly polarized feed network; the main feed port is connected below the extension of the equal power division circular-ring-shaped microstrip feeder line, and a small hole for exposing the main feed port is formed in the metal plate on the lower surface of the feed network layer;

The following is a more specific example:

referring to fig. 1 to 2, the present embodiment is composed of a matching dielectric layer, a radiation dielectric layer, a circular polarization feed network, a feed network layer, a feed probe, a total feed port, and the like.

The metamaterial microstrip patch units 2 are microstrip antennas with the size of 2mm multiplied by 2mm, the gaps between the front and the rear are 1.25mm, a rectangular annular structure is formed, the upper portions of first dielectric plates 3 with the dielectric constants of 2.2 and the height of 2mm form matching dielectric layers, radiation patches are located between the first dielectric plates 3 and second dielectric plates 5 with the dielectric constants of 21.2 and the height of 7mm, the radiation patches are rectangular patches with the side length of 21mm, and the radiation patches and the second dielectric plates 5 form radiation dielectric layers. The radiating patch is fed by two feed probes.

The circularly polarized feed network comprises an equal-power-division circular-ring-shaped microstrip feeder line 1 and two unequal-length feed lines which are sequentially connected to the same end point of equal-power-division circular-ring-shaped microstrip feed, wherein the two unequal-length feed lines comprise a long feed line 7 and a short feed line 6, and the two feed lines are parallel to each other; which is located between the two feeding dielectric plates of the feeding network layer. The phase difference between the two unequal-length feed lines is 90 degrees, and the feed line close to the annular microstrip feed line is shorter than the other feed line.

The upper layer feed dielectric plate 9 has a dielectric constant of 7 and a thickness of 1mm, is positioned below the radiation dielectric layer, and is provided with a metal plate therebetween, so that part of metal is corroded at the junction of the two feed probes and the metal plate to form a round hole in order to avoid short circuit.

The lower layer feed dielectric plate 8 has a dielectric constant of 7 and a thickness of 1mm, is positioned at the bottommost layer, and is provided with a metal plate at the bottom, so that part of metal is corroded at the junction of the main feed port 7 and the metal plate to form a round small hole in order to avoid short circuit.

Wherein, the total feeding port is coaxial feeding. The total feed port is connected below the extension 10 of the equal power division circular-ring-shaped microstrip feed line.

The circularly polarized feed network can be mirrored according to the structure to obtain opposite circularly polarized characteristics.

The circularly polarized antenna is simulated, the antenna has the characteristics of wide angle coverage, small standing-wave ratio, excellent wide angle axial ratio characteristic and the like, the overall size of the antenna is 34mm multiplied by 12mm, in the simulation result, the standing-wave ratio curve of the antenna is shown in figure 3, the standing-wave ratio curve is smaller than 2 in a required frequency band, the directional diagram curve of the antenna is shown in figure 4, the antenna gain is larger than 2.5dBi, the gain is reduced by smaller than 3.5dB within +/-60 degrees, and the axial ratio curve of the antenna beam is shown in figure 5, and is better than 3dB within +/-60 degrees.

The utility model discloses a theory of operation:

when a signal is transmitted, the signal generated by the transmitter enters the main feed port, the signal is subjected to equal power division through the circularly polarized feed network, the signal is transmitted in the network and respectively enters the two feed routing wires, 90-degree phase shift is realized due to different paths, the two feed detection wires are used for feeding the radiation patch, and the signal is radiated out through the radiation patch. The metamaterial microstrip patch unit 2 and the matching medium layer play a role in impedance matching.

When receiving signals, circularly polarized signals from the space enter the radiation patch after passing through the matching dielectric layer, and enter branch ports of the feed network along the two coaxial feed probes to form two paths of signals, the two paths of signals respectively carry out 90-degree phase shift through different paths, and the two paths of signals enter the receiving equipment through the synthesized port.

Claims

1. A circularly polarized microstrip antenna comprises a matching dielectric layer, a radiation dielectric layer and a feed network layer which are stacked from top to bottom; the device is characterized by further comprising a main feed port and two feed probes;

the two feed probes are connected to the lower surface of the radiation patch and are perpendicular to the lower surface of the radiation patch; the circularly polarized feed network comprises an equal-power-division annular microstrip feed line and two unequal-length feed lines which are sequentially connected to the same end point of the equal-power-division annular microstrip feed line, and the two unequal-length feed lines are parallel to each other; the tail ends of the two feed probes are respectively connected to two end points of the circularly polarized feed network; the main feed port is connected below the extension of the equal power division circular-ring-shaped microstrip feeder line, and a small hole for exposing the main feed port is formed in the metal plate on the lower surface of the feed network layer;

the phase difference between the two unequal-length feed lines is 90 degrees, and the feed line close to the annular microstrip feed line is shorter than the other feed line; and the feed probe and the total feed port are not in contact with the metal plates on the upper surface and the lower surface of the feed network layer.

2. The microstrip antenna of claim 1 wherein the microstrip patch element group is a rectangular ring structure formed by a plurality of metamaterial microstrip patch elements.

3. The circularly polarized microstrip antenna of claim 1 wherein the radiating patch is located directly below the set of microstrip patch elements.