CN219498172U - Common-caliber antenna array - Google Patents

Abstract

The utility model provides a common-caliber antenna array, which comprises a plurality of common-caliber antenna subarrays and a PCB layer; each common-caliber antenna subarray consists of a receiving antenna and a plurality of transmitting antennas positioned around the receiving antenna; the PCB layer consists of a conductive layer and a plurality of dielectric layers; in the common-caliber antenna subarrays, a plurality of transmitting antennas are arrayed in a sequential rotation mode; the receiving antenna at least comprises a receiving radiation patch, orthogonal feed through holes and feed disks, and each feed disk and one orthogonal feed through hole are arranged in a concentric circle; the radiation receiving patch is coupled with the feed disc for feeding; the transmitting antenna comprises at least a transmitting radiating patch and a feeding point. The feed disc and the radiation patch of the receiving antenna adopt coupling feed, so that the strong inductance effect of the antenna radiation surface and the conductive layer in the PCB layer is counteracted, and the transmitting antenna adopts a subarray form of sequential rotation, so that the axial ratio of the antenna can be reduced. The transceiver antenna is integrated in the same PCB layer, so that the compact and low-profile application of the common-caliber antenna array is realized.

Description

Common-caliber antenna array

Technical Field

The utility model relates to the technical field of microwave antennas, in particular to a common-caliber antenna array.

Background

In the phased array antenna system with limited size and weight, in order to reduce the aperture of the antenna as far as possible, antennas receiving and transmitting different frequency bands are generally integrated into a uniform aperture, and a common aperture antenna is one of ways to solve the problem. The common aperture antenna is an antenna form which allows multiple pairs of antennas of different polarizations in different frequency bands to operate simultaneously in the same aperture plane. The carrier space is fully utilized by reasonable layout in space, and electromagnetic coupling between antennas with different working frequencies is reduced, so that multiple antennas with different functions can work independently without mutual influence. Compared with the independent placement of multiple antennae, the common caliber antenna greatly saves the space occupied by the antennae, and the multiple antennae refer to antennae with different structural forms, rather than the antenna units with the same structural form in the traditional antenna array. In order to meet the grating lobe condition of two-dimensional large-angle scanning of the array antenna, the distance between array antenna units is usually smaller than one half wavelength, if the receiving and transmitting antennas are inherited in the same caliber, the frequency ratio between the receiving and transmitting antennas is generally required to be larger than 2, and when the laminated three-dimensional array sub-units are adopted, the distance between the antennas can be reduced, but the section height is increased, so that the method is extremely unfavorable for low-section application.

Disclosure of Invention

The present utility model is directed to overcoming at least one of the above-mentioned drawbacks of the prior art, and providing a common aperture antenna array for solving the problem that the cross-sectional height of the existing common aperture antenna is increased to meet the grating lobe condition of the transceiver antenna.

The technical scheme adopted by the utility model comprises the following steps:

the utility model provides a common-caliber antenna array, which comprises a plurality of common-caliber antenna subarrays and a PCB layer; each common-caliber antenna subarray consists of a receiving antenna and a plurality of transmitting antennas positioned around the receiving antenna; the receiving antenna and the transmitting antenna are both arranged in the PCB layer; the PCB layer consists of a conductive layer and a plurality of dielectric layers; in the common-caliber antenna subarrays, a plurality of transmitting antennas are arrayed in a sequential rotation mode; the receiving antenna at least comprises a receiving radiation patch, a plurality of orthogonal feed through holes and a plurality of feed disks; in the PCB layer, the radiation receiving patch and the feeding disc are arranged on the same layer, and the orthogonal feeding via hole extends from the layer where the feeding disc is positioned to the conducting layer; the radiation receiving patch is coupled with the feed disc for feeding; the transmitting antenna at least comprises a plurality of transmitting radiation patches and a feeding point; in the PCB layer, the feeding point is located at the same layer as the at least one radiation emitting patch and extends to the conductive layer.

In the common-caliber antenna array provided by the utility model, each common-caliber antenna subarray consists of the receiving antenna and the transmitting antennas arranged around the receiving antenna, so that the receiving and transmitting antennas are placed at the same caliber. The feed disc of the receiving antenna is not in direct contact with the radiation patch, the feed is performed in a coupling feed mode, the strong inductance effect of the antenna radiation surface and the conductive layer in the PCB layer is counteracted, and secondly, the transmitting antenna is in a subarray mode of sequential rotation, so that the axial ratio of the antenna can be reduced. In the whole, the receiving and transmitting antenna is integrated in the same PCB layer, so that the compact and low-profile application of the common-caliber antenna array is realized.

Further, the receiving antenna also comprises a plurality of perturbation metal disc knots; and a plurality of perturbation metal disc branches positioned on different layers in the PCB layer are arranged at each orthogonal feed through hole, and the orthogonal feed through hole passes through the centers of the perturbation metal disc branches.

The perturbation metal disc branch is used for increasing the capacitive component of the receiving antenna, and can offset the strong inductive component generated between the receiving radiation patch and the conducting layer due to the close distance, so that the return loss of the antenna is optimized, and the bandwidth of the antenna is expanded.

Further, the radiation emitting patches include an upper radiation patch and a lower radiation patch; the feed point and the lower radiation patch are arranged on the same layer; two ends of the lower radiation patch are respectively extended with at least one radiation branch.

In the transmitting antenna, the transmitting radiation patch comprises an upper layer of radiation patch and a lower layer of radiation patch, and the mode of laminated radiation patches is adopted, so that the working bandwidth of the transmitting antenna can be further expanded. Secondly, the radiation branches extending from the lower radiation patch are beneficial to optimizing the axial ratio of the transmitting antenna.

Further, the upper layer radiation patch is rectangular, and the lower layer radiation patch is circular.

Further, at least one radiation branch extending from both ends of the lower radiation patch is used to delay the edge current phase of the same lower radiation patch by 90 °.

The radiation branches respectively stretched out from the two ends of the lower radiation patch delay the edge current phase in the radiation patch by 90 degrees, so that circularly polarized electromagnetic waves are formed conveniently, and the axial ratio of the transmitting antenna is optimized.

Further, the upper radiation patch and the radiation receiving patch are located on the same layer of the PCB layer.

Further, at least one perturbation metal disc branch arranged at each orthogonal feed via is positioned on the same layer as the lower radiation patch.

Further, the radiation receiving patches are cross-shaped; in the common aperture antenna subarray, a plurality of transmitting antennas are positioned at the crisscross empty positions of the receiving radiation patch.

Because the receiving radiation patch is in a cross shape, at least 4 cross gaps are formed, the transmitting antenna can be arranged in the cross gaps, the patch shape can well vacate space for the transmitting antenna to be placed, and grating lobes caused by overlarge space between the transmitting antennas are avoided.

Further, each common-caliber antenna subarray consists of 1 receiving antenna and 4 transmitting antennas positioned around the receiving antenna; each transmit antenna is located at 1 crisscross null of the receive radiating patch.

Further, in the common aperture antenna subarray, each transmitting antenna is obtained by rotating the previous transmitting antenna in the counterclockwise direction by 90 ° around its own center in the counterclockwise direction.

The transmitting antennas are arrayed in a sequential rotation mode, so that the axial ratio of the antennas is reduced.

Compared with the prior art, the utility model has the beneficial effects that:

the utility model provides a compact low-profile common-caliber antenna array, each common-caliber antenna subarray consists of a receiving antenna and transmitting antennas arranged around the receiving antenna, and a receiving antenna and a transmitting antenna are integrated in the same PCB layer, so that the receiving antenna and the transmitting antenna are placed in the same caliber and are compact in position. The feed disk of the receiving antenna and the radiation patch are fed in a coupling feed mode, so that the strong inductance effect of the antenna radiation surface and the conductive layer in the PCB layer is counteracted, the return loss of the antenna is further optimized, and the bandwidth of the antenna is expanded. The transmitting antenna adopts a subarray form of sequential rotation, so that the axial ratio of the antenna is effectively reduced.

Drawings

Fig. 1 is a schematic layout diagram of a common aperture antenna array in this embodiment.

Fig. 2 is a schematic diagram of the composition of the common aperture antenna subarray a in this embodiment.

Fig. 3 is a schematic structural diagram of a PCB layer and a transceiver antenna in the present embodiment.

Fig. 4 is a schematic side view of the receiving antenna 1 in this embodiment.

Fig. 5 is a schematic top view of the receiving antenna 1 in this embodiment.

Fig. 6 is a schematic structural diagram of the upper layer radiation patch 21 of the transmitting antenna 2 in this embodiment.

Fig. 7 is a schematic diagram of the structure of the lower radiation patch 23 of the transmitting antenna 2 in this embodiment.

Fig. 8 shows the gain simulation results of the 4 common-aperture antenna subarrays a in the receiving frequency band in this embodiment.

Fig. 9 is an axial ratio simulation result of the 4 common-aperture antenna subarrays a in the receiving frequency band in this embodiment.

Fig. 10 is a simulation result of the active return loss of the receiving antenna 1 under the periodic boundary in the present embodiment.

Fig. 11 shows the gain simulation results of the 4 common-aperture antenna subarrays a in the transmitting frequency band in this embodiment.

Fig. 12 is an axial ratio simulation result of the 4 common-caliber antenna subarrays a in the transmitting frequency band in the present embodiment.

Fig. 13 is a simulation result of active return loss of the transmitting antenna 2 under the periodic boundary in the present embodiment.

Detailed Description

The drawings are for illustrative purposes only and are not to be construed as limiting the utility model. For better illustration of the following embodiments, some parts of the drawings may be omitted, enlarged or reduced, and do not represent the actual product dimensions; it will be appreciated by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

Example 1

The embodiment provides a common-caliber antenna array, which can realize common-caliber integration of a receiving antenna and a transmitting antenna, and the receiving antenna and the transmitting antenna are integrated in the same PCB layer, so that the compact and low-profile application of the antenna array is realized.

As shown in fig. 1, the common-aperture antenna array includes a plurality of common-aperture antenna sub-arrays a.

Each common-caliber antenna subarray A consists of a receiving antenna and a plurality of transmitting antennas positioned around the receiving antenna. In this embodiment, the operating frequency band of the receiving antenna is 1.92GHz-1.98GHz (L-band), and the operating frequency band of the transmitting antenna is 3.44GHz-3.66GHz (S-band).

In a specific embodiment, as shown in fig. 2, each common-aperture antenna subarray a includes a receiving antenna 1 and four transmitting antennas, where the four transmitting antennas are located around the receiving antenna, and are respectively a transmitting antenna 2, a transmitting antenna 3, a transmitting antenna 4 and a transmitting antenna 5.

In the common aperture antenna subarray, transmitting antennas are arrayed in a sequential rotation mode, so that the axial ratio of the antennas is reduced. Specifically, as shown in fig. 2, the transmitting antenna 3 is obtained by rotating the transmitting antenna 2 by 90 ° counterclockwise about its own center, the transmitting antenna 4 is obtained by rotating the transmitting antenna 3 by 90 ° counterclockwise about its own center, and the transmitting antenna 5 is obtained by rotating the transmitting antenna 4 by 90 ° counterclockwise about its own center.

In the common aperture antenna array, the receiving antenna and the transmitting antenna are both disposed in the PCB layer. The PCB layer is composed of a conductive layer and a plurality of dielectric layers. In a specific embodiment, as shown in fig. 3, the PCB layer is composed of five dielectric layers and one conductive layer, which are sequentially arranged, namely, a dielectric layer 31, a dielectric layer 32, a dielectric layer 33, a dielectric layer 34, a dielectric layer 35 and a conductive layer 36. In this embodiment, the dielectric layers 31 to 35 are dielectric plates having a dielectric constant of 3.48, and the conductive layer 36 is a metal ground.

In the common aperture antenna array, the receiving antenna at least comprises a receiving radiation patch, a plurality of orthogonal feed through holes and a plurality of feed disks, wherein each feed disk and one orthogonal feed through hole are arranged in concentric circles. As shown in fig. 4 and 5, the receiving antenna 1 at least includes a receiving radiation patch 17, two orthogonal feed vias are respectively an orthogonal feed via 11 and an orthogonal feed via 12, two feed disks are respectively a feed disk 111 and a feed disk 112, the feed disk 111 and the orthogonal feed via 11 are arranged in concentric circles, and the feed disk 112 and the orthogonal feed via 12 are arranged in concentric circles.

In a preferred embodiment, as shown in fig. 2, 4 and 5, the receiving radiation patch 17 has a cross shape with 4 cross gaps, and the transmitting antenna 2, the transmitting antenna 3, the transmitting antenna 4 and the transmitting antenna 5 may be respectively disposed in one cross gap. Compared with the traditional rectangular patch, the receiving radiation patch 17 provided by the embodiment can well vacate space for the transmitting antennas 2-5 to be placed, and grating lobes caused by overlarge space between the transmitting antennas are avoided. In this embodiment, the spacing between the transmitting antennas is 42mm and the spacing between the receiving antennas is 84mm.

As shown in fig. 3, in the PCB layer, the radiation receiving patch 17 is provided on the same layer as the feed pads 111 and 112, and the orthogonal feed vias 11 and 12 extend from the layers of the feed pads 111 and 112 to the conductive layer 36. The receiving radiation patch 17 is not in direct contact with the feeding disc 111 and the feeding disc 112, and feeding is performed in a coupling feeding mode, so that the strong inductance effect of the antenna radiation surface and the conductive layer in the PCB layer is counteracted, the capacitive component of the antenna is further increased, and the return loss and other electrical properties of the antenna are optimized.

In a preferred embodiment, the receiving antenna 1 further comprises a number of perturbation metal disc knots. Each orthogonal feed via hole is provided with a plurality of perturbation metal disc branches positioned at different layers in the PCB layer, as shown in fig. 2-4, each orthogonal feed via hole 11 is provided with four perturbation metal disc branches, namely a perturbation metal disc branch 13, a perturbation metal disc branch 14, a perturbation metal disc branch 15 and a perturbation metal disc branch 16, which are positioned at different layers in the PCB layer, and the orthogonal feed via hole 11 passes through the centers of the perturbation metal disc branches 13-16. Likewise, the same number of perturbation metal disc stubs are provided at the orthogonal feed-through 12 and the centers of the four perturbation metal disc stubs are traversed by the orthogonal feed-through 12. The perturbation metal disc branch is used for increasing the capacitive component of the receiving antenna, and can offset the strong inductive component generated between the receiving radiation patch 17 and the conductive layer 36 due to the close distance, thereby optimizing the return loss of the antenna and expanding the bandwidth of the antenna.

In the common aperture antenna array, the transmitting antenna at least comprises a plurality of transmitting radiation patches and a feeding point. As shown in fig. 2, 3, 6 and 7, taking the transmitting antenna 2 as an example, the transmitting antenna 2 includes an upper layer radiation patch 21, a lower layer radiation patch 23 and a feeding point 24. In a specific embodiment, the upper radiating patch 21 is rectangular and the lower radiating patch 23 is circular.

As shown in fig. 7, two ends of the lower radiation patch 23 are respectively extended with one radiation branch, namely a radiation branch 26 and a radiation branch 27. In a specific embodiment, the radiating branches 26 and 27 are rectangular metal branches for delaying the edge current phase of the lower radiating patch 23 by 90 ° so as to form circularly polarized electromagnetic waves for optimizing the axial ratio of the transmitting antenna.

As shown in fig. 3, in the PCB layer, the feeding point 24 is provided at the same layer as the lower radiation patch 23 and extends to the conductive layer 36. The upper layer of radiating patches 21 is located on the same layer as the receiving radiating patches 17. The perturbation metal disc branch 14 arranged at the position of the orthogonal feed through hole 11 and the lower-layer radiation patch 23 are positioned at the same layer, and similarly, the perturbation metal disc branch which is positioned at the position of the orthogonal feed through hole 12 and the lower-layer radiation patch 23 are also arranged at the same layer.

The remaining transmitting antennas 3 to 5 have the same structure as the transmitting antenna 2.

As shown in fig. 8, in this embodiment, the gain simulation result of the common aperture antenna subarray a in the receiving band shows that the efficiency of the antenna in the receiving band is more than 85%, and the antenna has good electrical performance.

As shown in fig. 9, in this embodiment, the axial ratio simulation result of the common aperture antenna subarray a in the receiving frequency band is that the axial ratio of the antenna in the receiving frequency band is far less than 3dB, and the circular polarized wave performance is good.

As shown in fig. 10, in this embodiment, the active return loss of the receiving antenna 1 at the periodic boundary is less than-9.5 dB in the operating frequency band, and the electrical performance is good.

As shown in fig. 11, in this embodiment, the gain simulation result of the common aperture antenna subarray a in the transmitting frequency band shows that the efficiency of the antenna in the transmitting frequency band reaches over 70%, and is slightly lower than the receiving efficiency, but meets the engineering application requirements.

As shown in fig. 12, in this embodiment, the axial ratio simulation result of the common aperture antenna subarray a in the transmitting frequency band is that the axial ratio of the antenna in the transmitting frequency band is far less than 3dB, and the circular polarized wave performance is good.

As shown in fig. 13, in this embodiment, the active return loss of the transmitting antenna 2 at the periodic boundary is less than-9.5 dB in the operating frequency band, and the electrical performance is good.

It should be understood that the foregoing examples of the present utility model are merely illustrative of the present utility model and are not intended to limit the present utility model to the specific embodiments thereof. Any modification, equivalent replacement, improvement, etc. that comes within the spirit and principle of the claims of the present utility model should be included in the protection scope of the claims of the present utility model.

Claims (10)

1. A common-caliber antenna array comprises a plurality of common-caliber antenna subarrays and a PCB layer;

each common-caliber antenna subarray consists of a receiving antenna and a plurality of transmitting antennas positioned around the receiving antenna;

the receiving antenna and the transmitting antenna are both arranged in the PCB layer; the PCB layer consists of a conductive layer and a plurality of dielectric layers;

it is characterized in that the method comprises the steps of,

in the common-caliber antenna subarrays, a plurality of transmitting antennas are arrayed in a sequential rotation mode;

the receiving antenna at least comprises a receiving radiation patch, a plurality of orthogonal feed through holes and a plurality of feed disks;

in the PCB layer, the radiation receiving patch and the feeding disc are arranged on the same layer, and the orthogonal feeding via hole extends from the layer where the feeding disc is positioned to the conducting layer; the radiation receiving patch is coupled with the feed disc for feeding;

the transmitting antenna at least comprises a plurality of transmitting radiation patches and a feeding point;

in the PCB layer, the feeding point is located at the same layer as the at least one radiation emitting patch and extends to the conductive layer.

2. The common aperture antenna array of claim 1, wherein the receive antenna further comprises a plurality of perturbation metal disc stubs;

and a plurality of perturbation metal disc branches positioned on different layers in the PCB layer are arranged at each orthogonal feed through hole, and the orthogonal feed through hole passes through the centers of the perturbation metal disc branches.

3. The co-aperture antenna array of claim 2, wherein the radiation-emitting patches comprise an upper radiation patch and a lower radiation patch; the feed point and the lower radiation patch are arranged on the same layer;

two ends of the lower radiation patch are respectively extended with at least one radiation branch.

4. A co-aperture antenna array according to claim 3 wherein the upper radiating patches are rectangular and the lower radiating patches are circular.

5. A co-aperture antenna array according to claim 3, wherein at least one radiating stub extending from each of the two ends of the lower radiating patch is adapted to delay the edge current phase of the same lower radiating patch by 90 °.

6. A co-aperture antenna array according to claim 3 wherein the upper radiating patch and the receiving radiating patch are located on the same layer of the PCB layer.

7. A co-aperture antenna array according to any of claims 2-6 wherein at least one perturbation metal disc stub provided at each orthogonal feed via is located on the same layer as the underlying radiating patch.

8. A co-aperture antenna array according to any of claims 1-6 wherein the receive radiating patches are cross-shaped; in the common aperture antenna subarray, a plurality of transmitting antennas are positioned at the crisscross empty positions of the receiving radiation patch.

9. The co-aperture antenna array of claim 8, wherein each co-aperture antenna subarray consists of 1 receiving antenna and 4 transmitting antennas located therearound; each transmit antenna is located at 1 crisscross null of the receive radiating patch.

10. A co-aperture antenna array according to any one of claims 1 to 6 or 9 wherein in the co-aperture antenna subarrays each transmit antenna is rotated 90 ° counter-clockwise around its own centre by the previous transmit antenna in the counter-clockwise direction.