Patent Description:
With the development of mobile communication technologies, plane resources for mounting an antenna are getting shorter and shorter, and the development of an antenna is focus on becoming smaller, lighter and multi-standard. In order to reduce a size and weight of the antenna and meet requirements for antenna multi-standard, the research on antenna fusion technologies becomes more important.

A traditional multi-standard integrated antenna array includes high-frequency arrays and low-frequency arrays arranged in a staggered manner. During usage, distortion is present in a direction pattern of the high-frequency array, coupling between high-frequency bands low-frequency bands is serious and it is difficult to meet actual requirements. Therefore, how to improve the performance of a multi-standard integrated antenna array without increasing the size of the antenna is a problem that needs to be solved.

<CIT> provides a multi-frequency antenna array, wherein each row of the multi-frequency antenna array comprises a plurality of high-frequency radiation units and a plurality of low-frequency radiation units; the axial distance between two adjacent rows is D; for any row in the multi-frequency antenna array, the distance between the centers of two adjacent high-frequency radiation units is L; the distance between the centers of two adjacent low-frequency radiation units is n*L; any low-frequency radiation unit is located in the midpoint of the lines between two high-frequency radiation units adjacent to the any low-frequency radiation unit; for any two adjacent rows in the multi-frequency antenna array, any high-frequency radiation unit in the first row is located on the central axis of the lines between two adjacent high-frequency radiation units of the second row; and any low-frequency radiation unit in the first row is located on the central axis of the lines between two adjacent low-frequency radiation units of the second row. The multi-frequency antenna array provided by the embodiment of the invention can effectively reduce the coupling effect between various frequencies and improve the performance index.

<CIT> relates to a miniaturized multi-system multi-band fusion base station antenna. The antenna comprises a bottom plate, and a reflecting plate and a reflecting plate are respectively arranged on two long edges of the bottom plate; a reflecting plate is arranged on one short edge of the bottom plate; the bottom plate is provided with a first high-frequency radiation antenna array, a third high-frequency radiation antenna array, a first low-frequency radiation antenna array, a fifth high-frequency radiation antenna array, a sixth high-frequency radiation antenna array, a second low-frequency radiation antenna array, a fourth high-frequency radiation antenna array and a second high-frequency radiation antenna array which are sequentially arranged in the direction from the first reflecting plate to the second reflecting plate. Each array comprises a plurality of high-frequency oscillators, high-frequency oscillators, high-frequency oscillators, high-frequency oscillators, high-frequency oscillators, high-frequency oscillators, low-frequency oscillators and low-frequency oscillators which are arrayed into a straight line; and first long isolation strips are arranged between the first high-frequency radiation antenna array and the third high-frequency radiation antenna array and between the fourth high-frequency radiation antenna array and the second high-frequency radiation antenna array.

<CIT> provides a multi-standard multi-port fusion antenna, comprising a high-frequency antenna array, a high-frequency antenna array and a low-frequency antenna array, the high-frequency antenna array supports horizontal plane beamforming, the high-frequency antenna array does not support horizontal plane beamforming, and the low-frequency antenna array does not support horizontal plane beamforming; a reflector and a reflector are provided, the reflector is higher than the reflector; the high-frequency antenna array is provided on the reflector, and the high-frequency antenna array is placed on the side of the high-frequency antenna array; part or all of the vibrators of the low-frequency antenna array are embedded in the high-frequency antenna array, and the embedded part is not coplanar with the reflector.

The present application provides a multi-standard integrated antenna array capable of solving the defects of serious coupling between high-frequency bands and low-frequency bands of the multi-standard integrated antenna array in the related art.

The present application provides a multi-standard integrated antenna array, including a reflection plate, three or more high-frequency arrays and one or more low-frequency arrays, where the high-frequency arrays and the low-frequency arrays are mounted on the reflection plate, each low-frequency array includes one or more cross-shaped low-frequency radiation units, each high-frequency array includes several high-frequency radiation units, each cross-shaped low-frequency radiation unit is embedded in horizontal and vertical central axes of the high-frequency radiation units and a projection of each cross-shaped low-frequency radiation unit on the reflection plate is located outside a projection of each high-frequency radiation unit on the reflection plate.

In the multi-standard integrated antenna array according to the present application, a window-shaped (that is, a shape of four (<NUM>*<NUM>) squares combined together) low-frequency radiation unit is mounted at a head end and a tail end of each of the low-frequency arrays, respectively.

In the multi-standard integrated antenna array according to the present application, a central axis of the window-shaped low-frequency radiation unit and a central axis of the cross-shaped low-frequency radiation unit are staggered.

In the multi-standard integrated antenna array according to the present application, the high-frequency radiation units, the cross-shaped low-frequency radiation units and the window-shaped low-frequency radiation units are any one of a printed circuit board, a metal die-casting radiation unit, a sheet metal molded radiation unit and a patch radiation unit.

In the multi-standard integrated antenna array according to the present application, the number of the high-frequency arrays is six, the number of the low-frequency arrays is two, and cross-shaped low-frequency radiation units in two low-frequency arrays are embedded in a second row of the high-frequency array and a fifth row of the high-frequency array correspondingly.

In the multi-standard integrated antenna array according to the present application, high-frequency radiation units of a first high-frequency array of the high-frequency arrays and high-frequency radiation units of a second high-frequency array of the high-frequency arrays adjacent to the first high-frequency array are arranged in a staggered manner.

In the multi-standard integrated antenna array according to the present application, a spacing between two adjacent high-frequency radiation units in the same high-frequency array is denoted as L, and a staggered spacing between the high-frequency radiation units in two adjacent high-frequency arrays is <NUM>/<NUM>.

In the multi-standard integrated antenna array according to the present application, a spacing between the cross-shaped low-frequency radiation units is two times of a spacing between high-frequency radiation units in two adjacent high-frequency arrays.

In the multi-standard integrated antenna array according to the present application, a low-frequency baffle is provided between two low-frequency radiation units.

In the multi-standard integrated antenna array according to the present application, the height of the low-frequency baffle is <NUM> to <NUM>.

In the multi-standard integrated antenna array according to the present application, the cross-shaped low-frequency radiation units are arranged on the horizontal and vertical central axes of the high-frequency radiation units, the width of the antenna with integrated low-frequency arrays and the high-frequency arrays is reduced. In addition, a projection of each cross-shaped low-frequency radiation unit on the reflection plate is located outside the projection of the high-frequency radiation units on the reflection plate, which decreases the coupling between the high-frequency arrays and the low-frequency arrays, and optimizes the performance of the antenna.

To more clearly illustrate solutions of the present application or in the related art, accompanying drawings used in the description of the embodiments or the related art are briefly introduced below. The drawings in the following description only show some embodiments of the present application. For those of ordinary skilled in the art, other drawings can also be obtained based on these drawings without creative effort.

In order to make the objective, solutions and advantages of the present application clearer, the solutions in the present application will be described clearly and completely below in conjunction with the accompanying drawings in the present application. The described embodiments are a part of the embodiments of the present application, and not all of them. Based on the embodiments in the present application, all other embodiments obtained by those of ordinary skilled in the art without making creative labor fall within the scope of protection of the present application.

In the description of the embodiments of the present application, it should be noted that, unless otherwise expressly specified and limited, the terms "first" and "second" are numbered for the purpose of clearly describing the product components and do not imply any substantial difference. The directions of "top", "bottom", "left", and "right" are based on the directions shown in the attached drawings. Those of ordinary skill in the art can understand the specific meanings of the above terms in the embodiments of the present application according to specific situations.

In the description of the present application, it should be noted that the terms "mounted", "connected to" and "connected with" should be understood in a broad sense, unless otherwise expressly specified and limited. For example, it may be fixedly connected or may be detachably connected or integrally connected; it can be mechanical connection or electrical connection; it can be directly connected, or indirectly connected through an intermediate medium, and it can be internal communication between two elements. Those of ordinary skill in the art can understand the specific meanings of the above terms in the embodiments of the present application according to specific situations.

The structure of the multi-standard integrated antenna array according to the present application is described below in conjunction with <FIG>.

As shown in <FIG>, the multi-standard integrated antenna array according to the present application includes a reflection plate <NUM>, three or more high-frequency arrays <NUM> and one or more low-frequency arrays <NUM>, where the high-frequency arrays <NUM> and the low-frequency array <NUM> are mounted on the reflection plate <NUM>. Each low-frequency array <NUM> includes one or more cross-shaped low-frequency radiation unit <NUM>, each high-frequency array <NUM> includes several high-frequency radiation units <NUM>, each cross-shaped low-frequency radiation unit <NUM> is embedded in horizontal and vertical central axes of the high-frequency radiation units <NUM> and a projection of each cross-shaped low-frequency radiation unit <NUM> on the reflection plate <NUM> is located outside the projection of each high-frequency radiation unit <NUM> on the reflection plate <NUM>.

In the multi-standard integrated antenna array according to the present application, the cross-shaped low-frequency radiation units <NUM> are arranged on the horizontal and vertical central axes of the high-frequency radiation units <NUM>, the width of the antenna after the fusion of the low-frequency arrays and the high-frequency arrays is reduced. In addition, a projection of each cross-shaped low-frequency radiation unit <NUM> on the reflection plate is located outside the projection of each high-frequency radiation unit <NUM> on the reflection plate, the coupling between the high-frequency arrays and the low-frequency arrays is decreased and the performance of the antenna is optimized.

In an embodiment, there are one low-frequency array <NUM> and three high-frequency arrays <NUM>. The low-frequency array <NUM> is embedded in the high-frequency arrays <NUM> located in the middle, each cross-shaped low-frequency radiation unit <NUM> is located between two adjacent high-frequency radiation units <NUM> in the high-frequency arrays <NUM>. A horizontal axis of each cross-shaped low-frequency radiation unit <NUM> overlaps with a horizontal axis of each high-frequency array <NUM>, and a vertical axis of the cross-shaped low-frequency radiation unit <NUM> coincides with a vertical axis of each high-frequency radiation unit <NUM>. Each cross-shaped low-frequency radiation unit <NUM> is arranged in the horizontal and vertical central axes of the high-frequency radiation units to reduce the width of the antenna.

In another embodiment, as shown in <FIG>, there are two low-frequency arrays <NUM>, i.e., the first low-frequency array and the second low-frequency array; and there are six high-frequency arrays <NUM>, i.e., a first row, a second row, a third row, a fourth row, a fifth row and a sixth row arranged from top to bottom. The first low-frequency array is embedded in the second row of high-frequency array <NUM>, the second low-frequency array embedded in the fifth row of high-frequency array <NUM>. The arrangement manner of the cross-shaped low-frequency radiation unit <NUM> in the high-frequency radiation unit <NUM> is similar to the arrangement manner of the low-frequency array in the three high-frequency arrays, and will not be repeated.

On the basis of the above embodiments, a window-shaped low-frequency radiation unit <NUM> is mounted at a head end and a tail end of each of the low-frequency arrays <NUM>, respectively. It should be noted that a window-shaped structure refers to a shape of four squares combined together. That is, a window-shaped low-frequency radiation unit <NUM> is mounted at a head end and a tail end of the cross-shaped low-frequency radiation unit <NUM>. Due to the window-shaped low-frequency radiation unit <NUM> having better gain and better wave width indicators, the window-shaped low-frequency radiation unit <NUM> is combined with the cross-shaped low-frequency radiation unit <NUM> to form an array, which avoids dispersion of low-frequency horizontal wave in a width direction, improves the overall performance of the low-frequency array and optimizes the coverage effect of the antenna.

As shown in <FIG>, the transverse axis of the window-shaped low-frequency radiation unit <NUM> and the transverse axis of the cross-shaped low-frequency radiation unit <NUM> are staggered. The staggered spacing can be adjusted according to the gain and wave width indicator of the antenna.

As shown in <FIG>, there are six high-frequency arrays <NUM>, two low-frequency arrays <NUM>. The cross-shaped low-frequency radiation units <NUM> in two low-frequency arrays <NUM> are arranged in the second and fifth rows of high-frequency arrays <NUM> in a staggered manner.

In an embodiment, a low-frequency baffle <NUM> is provided between two low-frequency radiation units and the height of the low-frequency baffle <NUM> is <NUM>-<NUM>. In an embodiment, the height of the low-frequency baffle <NUM> is <NUM>. In another embodiment, the height of the low-frequency baffle <NUM> is <NUM>; and in yet another embodiment, the height of the low-frequency baffle <NUM> is <NUM>. A metal baffle <NUM> is an L-shaped plate, a horizontal plate of the metal baffle is fixed with the reflection plate <NUM>, and a vertical plate of the metal baffle <NUM> is located between two adjacent high-frequency arrays <NUM>. When there are multiple low-frequency arrays <NUM>, a low-frequency baffle <NUM> is provided between window-shaped low-frequency radiation units <NUM> of two adjacent low-frequency arrays <NUM>.

In an embodiment, high-frequency radiation units <NUM> of a first high-frequency array of the high-frequency arrays <NUM> and high-frequency radiation units <NUM> of a second high-frequency array of the high-frequency arrays <NUM> adjacent to the first high-frequency array are arranged in a staggered manner. As shown in <FIG> and <FIG>, a spacing between two adjacent high-frequency radiation units <NUM> in the same high-frequency array is L, and a lateral staggered spacing between the high-frequency radiation units <NUM> in two adjacent rows of high-frequency arrays <NUM> is <NUM>/<NUM>.

In an embodiment, a spacing between the cross-shaped low-frequency radiation units <NUM> is two times of a spacing between high-frequency radiation units <NUM> in two adjacent high-frequency arrays <NUM>. As shown in <FIG>, a spacing between two adjacent high-frequency radiation units <NUM> in the same row of high-frequency array is L, and a spacing between two adjacent cross-shaped low-frequency radiation unit in the same low-frequency array <NUM> is <NUM>.

In an embodiment, the high-frequency radiation units <NUM>, the cross-shaped low-frequency radiation units <NUM> and the window-shaped low-frequency radiation units <NUM> are any one of a printed circuit board, a metal die-casting radiation unit, a sheet metal molded radiation unit and a patch radiation unit. It should be noted that the high-frequency radiation units <NUM>, the cross-shaped low-frequency radiation units <NUM> and the window-shaped low-frequency radiation units <NUM> can be the same or different.

As shown in <FIG>, in the multi-standard integrated antenna array according to the embodiment of the present application, the high-frequency arrays <NUM> include a first high-frequency array, a second high-frequency array, a third high-frequency array, a fourth high-frequency array, a fifth high-frequency array and a sixth high-frequency array arranged sequentially from top to bottom and the low-frequency arrays <NUM> include a first low-frequency array and a second low-frequency array. Each low-frequency array <NUM> includes four cross-shaped low-frequency radiation units <NUM> and two window-shaped low-frequency radiation units <NUM> located at the head end and tail end of the cross-shaped low-frequency radiation units <NUM>. A low-frequency baffle <NUM> is provided between the two window-shaped low-frequency radiation units <NUM> at the corresponding ends. Each high-frequency array <NUM> includes multiple high-frequency radiation units <NUM>. As shown in <FIG>, each high-frequency radiation unit <NUM> includes a radiation arm for high-frequency radiation unit <NUM>, a base for high-frequency radiation unit <NUM>, and a director element for high-frequency radiation unit <NUM>. The cross-shaped low-frequency radiation unit <NUM> includes a base <NUM>, a radiation arm <NUM> and a balun <NUM>. An end of the balun <NUM> is connected with the radiation arm <NUM>, and another end of the balun <NUM> is connected with base <NUM>.

In an embodiment, the first low-frequency array is arranged in the second high-frequency array, and the second low-frequency array is arranged in the fifth high-frequency array. The transverse central axis of four cross-shaped low-frequency radiation units <NUM> in each low-frequency array <NUM> coincides with the transverse central axis of the high-frequency radiation units <NUM> in a corresponding high-frequency array <NUM>. Each cross-shaped low-frequency radiation unit <NUM> is arranged between two adjacent high-frequency radiation units <NUM>, that is, a spacing between two adjacent high-frequency radiation units <NUM> is L, and the spacing between two adjacent cross-shaped low-frequency radiation units <NUM> is <NUM>. The transverse central axis of the window-shaped low-frequency radiation units <NUM> at the head end and tail end and the transverse central axes of the cross-shaped low-frequency radiation units <NUM> are staggered in a longitudinal direction, and the staggered distance is adjusted according to the performance of the antenna. Cross-shaped low-frequency radiation units <NUM> in the first low-frequency array and the second low-frequency array are arranged in a staggered manner and a transverse staggered spacing between the cross-shaped low-frequency radiation units <NUM> is <NUM>. Similarly, the two adjacent rows of high-frequency radiation units <NUM> are arranged in a staggered manner and a transverse staggered spacing between the high-frequency radiation units <NUM> is <NUM>. A low-frequency baffle 5is provided between two adjacent rows of low-frequency radiation units and the height of the low-frequency baffle <NUM> is <NUM> to <NUM>.

Claim 1:
A multi-standard integrated antenna array, comprising: a reflection plate (<NUM>), three or more high-frequency arrays (<NUM>) and one or more low-frequency arrays (<NUM>),
wherein the high-frequency arrays (<NUM>) and the low-frequency arrays (<NUM>) are mounted on the reflection plate (<NUM>), each low-frequency array (<NUM>) comprises one or more cross-shaped low-frequency radiation units (<NUM>),
each high-frequency array (<NUM>) comprises several high-frequency radiation units (<NUM>), each cross-shaped low-frequency radiation unit (<NUM>) is embedded in horizontal and vertical central axes of the high-frequency radiation units (<NUM>) and a projection of each cross-shaped low-frequency radiation unit (<NUM>) on the reflection plate (<NUM>) is located outside a projection of each high-frequency radiation unit (<NUM>) on the reflection plate (<NUM>),
characterized in that
further low-frequency radiation unit (<NUM>) is mounted at a head end and a tail end of each of the low-frequency arrays (<NUM>) respectively, wherein a shape of the low-frequency radiation unit (<NUM>) is a <NUM> by <NUM> square grid.