阅读说明：本技术 阵列透镜、透镜天线和电子设备 (Array lens, lens antenna, and electronic apparatus ) 是由 杨帆 于 2019-10-29 设计创作，主要内容包括：本申请涉及一种阵列透镜、透镜天线和电子设备,阵列透镜包括：至少一介质层；至少两层阵列结构,介质层与阵列结构沿第一方向交替层叠设置；每一层阵列结构包括金属本体,金属本体上开设有多个呈阵列设置的缝隙单元,缝隙单元包括第一缝隙和环绕第一缝隙且与第一缝隙间隔设置的第二缝隙,至少两层阵列结构位于同一相对位置的多个缝隙单元在第一方向上同轴设置；其中,同一阵列结构中,多个第一缝隙在至少一个阵列方向上具有相对于阵列方向渐变的相对旋转角度；可对不同频段的相位分布进行补偿,能对电磁波进行汇聚,可使得该阵列透镜在更宽的频率范围内焦平面保持不变,大大减小偏焦波束增益的降幅,大幅提高透镜天线的扫描角度,覆盖范围大。(The present application relates to an array lens, a lens antenna, and an electronic apparatus, the array lens including: at least one dielectric layer; the array structure comprises at least two layers of array structures, and dielectric layers and the array structures are alternately stacked along a first direction; each layer of array structure comprises a metal body, a plurality of gap units arranged in an array mode are arranged on the metal body, each gap unit comprises a first gap and a second gap surrounding the first gap and arranged at intervals with the first gap, and the gap units of at least two layers of array structures located at the same relative position are coaxially arranged in a first direction; in the same array structure, the plurality of first slits have relative rotation angles gradually changing relative to the array direction in at least one array direction; the phase distribution of different frequency bands can be compensated, electromagnetic waves can be converged, the focal plane of the array lens can be kept unchanged in a wider frequency range, the amplitude reduction of the gain of a deflection focal beam is greatly reduced, the scanning angle of the lens antenna is greatly improved, and the coverage range is large.)

1. An array lens, comprising:

at least one dielectric layer;

the array structure comprises at least two layers of array structures, wherein the dielectric layers and the array structures are alternately stacked along a first direction; each layer of array structure comprises a metal body, a plurality of gap units arranged in an array mode are arranged on the metal body, each gap unit comprises a first gap and a second gap surrounding the first gap and arranged at intervals with the first gap, and the gap units, which are positioned at the same relative position, of the at least two layers of array structures are coaxially arranged in the first direction;

in the same array structure, the plurality of first slits have relative rotation angles gradually changed relative to the array direction in at least one array direction.

2. The array lens of claim 1, wherein at least three of the slit units in each layer of the array structure are in a two-dimensional array, the array direction of the two-dimensional array comprises a row direction and a column direction, and the first slits in the same array structure have gradually changed relative rotation angles in the row direction.

3. The array lens of claim 2, wherein the relative rotation angles of the plurality of first slits in the row direction symmetrically increase from the first center line of the two-dimensional array to the edge of the array, and are the same in the column direction in the same array structure.

4. The array lens of claim 2, wherein the plurality of first slits have gradually changing relative rotation angles in the column direction in the same array structure.

5. The array lens of claim 4, wherein the relative rotation angles of the plurality of first slits in the row direction increase symmetrically from a first centerline of the two-dimensional array to an array edge and the relative rotation angles in the column direction increase symmetrically from a second centerline of the two-dimensional array to an array edge in the same array structure.

6. The array lens of any of claims 1-5, wherein a plurality of the first slits have a gradual first slit size in at least one of the array directions in the same array structure.

7. The array lens of claim 6, wherein the first slit size of the plurality of first slits decreases symmetrically in the row direction from a first centerline of the two-dimensional array to an array edge in the same array structure, or/and the first slit size of the plurality of first slits decreases symmetrically in the column direction from a second centerline of the two-dimensional array to an array edge in the same array structure.

8. The array lens of claim 1, wherein the plurality of first slits coaxially arranged in the multi-layered array structure have a gradually changing first slit size in a first direction.

9. The array lens of claim 1, wherein the plurality of second slits have a gradual second slit unit size in at least one array direction in the same array structure.

10. The array lens according to claim 1, wherein the center distances of adjacent two of the second slits are equal in the array direction.

11. The array lens of claim 1, wherein the first slit comprises at least one rectangular slit or at least one elliptical slit.

12. The array lens according to claim 11, wherein a plurality of the rectangular slits are arranged in parallel, and length dimensions of the rectangular slits in parallel directions are different; or the major axes of the elliptical slits are arranged in parallel, and the major axes of the elliptical slits are different in size.

13. The array lens of claim 1, wherein the first slit is a circular slit or a rectangular slit.

14. A lens antenna, comprising:

a feed array comprising a plurality of feed units;

an array lens as claimed in any one of claims 1 to 13 arranged in parallel with said array of feeds.

15. The lens antenna of claim 14, further comprising first and second parallel-arranged spacers, the feed array and the lens being disposed between the first and second spacers.

16. The lens antenna of claim 15, wherein the plane of the feed array is perpendicular to the plane of the first isolation plate, and the array direction of the feed array is parallel to one array direction of the array units.

17. An electronic device comprising the lens antenna according to any one of claims 14 to 16.

18. The electronic device of claim 17, further comprising:

the detection module is used for acquiring the beam signal intensity of the lens antenna when each feed source unit is in a working state;

the switch module is connected with the feed source array and used for selectively conducting a connecting path with any one feed source unit;

and the control module is respectively connected with the detection module and the switch module and is used for controlling the switch module according to the beam signal intensity so as to enable the feed source unit corresponding to the strongest beam signal intensity to be in a working state.

19. The electronic device according to claim 16, wherein the lens antenna is provided in plurality, and the electronic device further comprises a middle frame, the middle frame comprises a first side edge and a third side edge which are opposite to each other, and a second side edge and a fourth side edge which are opposite to each other, the second side edge is connected to one end of the first side edge and the third side edge, and the fourth side edge is connected to the other end of the first side edge and the third side edge; at least two of the first side, the second side, the third side and the fourth side are respectively provided with the lens antenna.

Technical Field

The present application relates to the field of antenna technology, and in particular, to an array lens, a lens antenna, and an electronic device.

Background

A lens antenna, an antenna capable of converting a spherical wave or a cylindrical wave of a point source or a line source into a plane wave by an electromagnetic wave to obtain a pencil-shaped, fan-shaped, or other shaped beam. By properly designing the surface shape and refractive index of the lens, the phase velocity of the electromagnetic wave is adjusted to obtain a planar wavefront on the radiation aperture. A typical lens antenna usually has a limited scanning angle, which is not favorable for covering a large range.

Disclosure of Invention

The embodiment of the application provides an array lens, a lens antenna and an electronic device, which can greatly reduce the amplitude reduction of the gain of a focusing beam, improve the scanning angle of the lens antenna and have a large coverage area.

An array lens, comprising:

at least one dielectric layer;

the array structure comprises at least two layers of array structures, wherein the dielectric layers and the array structures are alternately stacked along a first direction; each layer of array structure comprises a metal body, a plurality of gap units arranged in an array mode are arranged on the metal body, each gap unit comprises a first gap and a second gap surrounding the first gap and arranged at intervals with the first gap, and the gap units, which are positioned at the same relative position, of the at least two layers of array structures are coaxially arranged in the first direction;

in the same array structure, the plurality of first slits have relative rotation angles gradually changed relative to the array direction in at least one array direction.

In addition, a lens antenna is also provided, and the lens antenna comprises the array lens and a feed source array arranged in parallel with the array lens.

In addition, an electronic device is also provided, and the electronic device comprises the lens antenna.

The array lens, the lens antenna and the electronic equipment comprise at least one dielectric layer; at least one dielectric layer;

the array structure comprises at least two layers of array structures, wherein the dielectric layers and the array structures are alternately stacked along a first direction; each layer of array structure comprises a metal body, a plurality of gap units arranged in an array mode are arranged on the metal body, each gap unit comprises a first gap and a second gap surrounding the first gap and arranged at intervals with the first gap, and the gap units, which are positioned at the same relative position, of the at least two layers of array structures are coaxially arranged in the first direction; in the same array structure, the plurality of first slits have relative rotation angles gradually changing relative to the array direction in at least one array direction, so that phase distribution of different frequency bands can be compensated, electromagnetic waves can be converged, a focal plane of the array lens can be kept unchanged in a wider frequency range, the amplitude of gain reduction of a deflection focal beam is greatly reduced, and the scanning angle of the lens antenna is greatly improved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without any creative work.

FIG. 1 is a perspective view of an electronic device in one embodiment;

FIG. 2 is a schematic diagram of an embodiment of an array lens;

FIG. 3 is a schematic diagram of an embodiment of an array lens;

FIG. 4 is a schematic diagram of an embodiment of an array lens;

FIG. 5 is a schematic diagram of an embodiment of an array lens;

FIG. 6 is a schematic diagram of an embodiment of an array lens;

FIG. 7 is a schematic diagram of an embodiment of an array lens;

FIG. 8 is a schematic diagram of an embodiment of an array lens;

FIG. 9 is a schematic diagram of an embodiment of an array lens;

FIG. 10a is a schematic diagram of a lens antenna according to an embodiment;

FIG. 10b is a schematic diagram of a lens antenna according to an embodiment;

FIG. 11 is a block diagram of an electronic device in an embodiment;

FIG. 12 is a beam scanning pattern in one embodiment;

FIG. 13 is a schematic diagram of an electronic device including a lens antenna in one embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that, as used herein, the terms "first," "second," and the like may be used herein to describe various elements, but these elements are not limited by these terms. These terms are only used to distinguish one element from another element, and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present application, "plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

It will be understood that when an element is referred to as being "attached" to another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

In one embodiment, the electronic Device may be a communication module including a Mobile phone, a tablet computer, a notebook computer, a palm computer, a Mobile Internet Device (MID), a wearable Device (e.g., a smart watch, a smart bracelet, a pedometer, etc.), or other configurable array antenna Device.

As shown in fig. 1, in an embodiment of the present application, an electronic device 10 may include a housing assembly 110, a midplane 120, a display screen assembly 130, and a controller. The display screen assembly 130 is fixed to the housing assembly 110, and forms an external structure of the electronic device together with the housing assembly 110. The housing assembly 110 may include a middle frame 111 and a rear cover 113. The middle frame 111 may be a frame structure having a through hole. The middle frame 111 can be accommodated in an accommodating space formed by the display screen assembly and the rear cover 113. The rear cover 113 is used to form an outer contour of the electronic apparatus. The rear cover 113 may be integrally formed. In the molding process of the rear cover 113, structures such as a rear camera hole, a fingerprint recognition module, an antenna device mounting hole, etc. may be formed on the rear cover 113. The rear cover 113 may be a non-metal rear cover 113, for example, the rear cover 113 may be a plastic rear cover 113, a ceramic rear cover 113, a 3D glass rear cover 113, or the like. The middle plate 120 is fixed inside the housing assembly, and the middle plate 120 may be a PCB (Printed Circuit Board) or an FPC (Flexible Printed Circuit). An antenna module for transmitting and receiving millimeter wave signals may be integrated with the midplane 120, and a controller capable of controlling operations of electronic devices may be integrated therewith. The display screen component can be used for displaying pictures or fonts and can provide an operation interface for a user.

As shown in fig. 2, an embodiment of the present application provides an array lens. In one embodiment, the array lens includes at least two layers of array structures 210 and at least one dielectric layer 220, and the dielectric layers 220 and the array structures 210 are alternately stacked along a first direction. For example, the first layer to the third layer of the array lens along the first direction may include a layer array structure 210, a dielectric layer 220, and a layer array structure 210 in sequence.

In one embodiment, the array lens includes top and bottom layers disposed opposite one another. When the array lens includes multiple layers, i.e., a dielectric layer 220 and multiple layers of array structures 210, the top layer of the array lens may be the array structure 210 or the dielectric layer 220, and the bottom layer of the array lens may also be the array structure 210 or the dielectric layer 220, for example, the first layer to the mth layer of the array lens along the first direction may be the array structure 210, the dielectric layer 220, the array structures 210, …, and the array structure 210 in sequence. In the embodiment of the present application, the specific layer structure of the top layer and the bottom layer of the array lens 210 is not further limited.

The first direction may be a longitudinal direction (Z-axis direction) of the array lens, and may be a stacking direction of the array lens.

The dielectric layer 220 is a non-metal functional layer capable of supporting and fixing the array structure 210, and the dielectric layer 220 and the array structure 210 are alternately stacked, so that the interval distribution of the multi-layer array structure 210 can be realized, and the multi-layer array structure and the array structure 210 can jointly form a phase delay unit. Alternatively, when the thicknesses of the plurality of dielectric layers 220 in the first direction are equal, the plurality of array structures 210 are distributed at equal intervals.

In one embodiment, the dielectric layer 220 is made of an electrically insulating material, which does not interfere with the electric field of the electromagnetic wave. For example, the material of the dielectric layer 220 may be a PET (polyethylene terephthalate) material, an ARM composite material, which is generally a composite of silica gel, PET, and other specially processed materials. Optionally, each dielectric layer 220 is the same, e.g., thickness, material, etc.

The array structure 210 is a conductive functional layer capable of transmitting electromagnetic waves, and the multilayer array structure 210 and the multilayer dielectric layer 220 form an array lens having phase delay or realizing convergence of electromagnetic waves, and can emit incident electromagnetic waves in parallel or converge the incident electromagnetic waves in parallel to a focus.

Each layer of the array structure 210 includes a metal body, the metal body is provided with a plurality of slot units 211 arranged in an array, each slot unit 211 includes a first slot 211a and a second slot 211b surrounding the first slot 211a, that is, the second slot 211b may surround the first slot 211a and be arranged at an interval with the first slot 211a, that is, the first slot 211a is not communicated with the second slot 211 b.

In one embodiment, the first slit 211a is an elliptical slit or a rectangular slit; the second slit 211b is an annular slit, for example, an elliptical ring, a circular ring, a rectangular ring, or a square ring slit. The shapes of the first slit 211a and the second slit 211b in the slit unit 211 may be arbitrarily combined, and are not further limited in this application.

In one embodiment, the first slit 211a is coaxially disposed with the second slit 211b, that is, the center of the first slit 211a is coaxially disposed with the center of the second slit 211 b. Here, the center of the first slit 211a may be understood as a centroid of the first slit 211a, and the center of the second slit 211b may be understood as a centroid of the second slit 211 b. Each of the first slits 211a is rotatable around a central axis of the second slit 211 b. That is, the first slit 211a rotates around the center of the second slit 211 b.

In one embodiment, the first slit 211a and the second slit 211b opened in the array structure 210 both penetrate through the array structure 210, that is, the first slit 211a and the second slit 211b can be understood as through holes disposed in the array structure 210.

In one embodiment, the plurality of slit units 211 included in each layer of the array structure 210 may be in a two-dimensional array, i.e., the plurality of first slits 211a is also in a two-dimensional array. The two-dimensional array may include a row direction and a column direction. The plane of the array structure 210 is a plane formed by an X-axis and a Y-axis, wherein the X-axis is a row direction and the Y-axis is a column direction.

In one embodiment, each layer of the array structure 210 may be identical. For example, the shape, number, relative rotation angle gradient, array mode, thickness, material, etc. of the first slits 211a in the array structure 210.

The first slits 211a of the at least two-layer array structure 210 located at the same relative position are coaxially arranged in the first direction. That is, the first slits 211a in the multi-layer array structure 210 located at the same relative position are all located on the same axis. The axis is a straight line passing through any of the first slits 211a and parallel to the first direction (Z-axis direction). Further, each axis passes through the centroid of the first slit 211 a. The centroid can be understood as the center of the geometric shape of the first slit 211a, if the first slit 211a is a rectangular slit, the centroid is the intersection of the diagonals of the rectangle, if the first slit 211a is an elliptical slit, the centroid is the center of the ellipse.

In the present application, the plane of each layer of the array structure 210 may construct the same rectangular coordinate system, and the origin of the rectangular coordinate system may be at the center of the array, the edge of the array, or any other point of the array structure 210. The position of each first slit 211a in the rectangular coordinate system may be represented by coordinates (x, y). The coordinates of the first slits 211a in the multi-layer array structure 210 at the same relative position are the same. That is, the same coordinates are the same relative position.

In the present application, the array numbers are set according to the same rule for the first slits 211a in the array structure 210 of each layer, and the first slits 211a are sorted according to the array numbers. That is, the array numbers of the first slits 211a located at the same relative position in the multi-layer array structure 210 are the same.

In the same array structure 210, the plurality of first slits 211a have a gradually changing relative rotation angle with respect to the array direction in at least one array direction. In the present embodiment, the relative rotation angle may be understood as a rotation angle of the first slit 211a with respect to the row direction (X axis) or the column direction (Y axis). In the present embodiment, a relative rotation angle is taken as an example of a rotation angle of the first slit 211a with respect to the column direction (Y axis). .

In the above array lens, in the same array structure 210, the plurality of first slits 211a have a relative rotation angle gradually changing with respect to the array direction in at least one array direction, and when an electromagnetic wave enters the array lens along the first direction, the array lens can compensate phase distribution of different frequency bands, and can converge the electromagnetic wave, so that a focal plane of the array lens is kept unchanged in a wider frequency range, thereby greatly reducing the amplitude of gain reduction of a partial focal beam, and greatly improving the scanning angle of the lens antenna.

The lens antenna can realize the transceiving of 5G millimeter waves, wherein the millimeter waves refer to electromagnetic waves with the wavelength of millimeter order, and the frequency of the electromagnetic waves is about 20 GHz-300 GHz. The 3GP has specified a list of frequency bands supported by 5G NR, the 5G NR spectral range can reach 100GHz, and two frequency ranges are specified: frequency range 1 (FR1), i.e. the sub-6 GHz band, and Frequency range 2(FR2), i.e. the millimeter wave band. Frequency range of Frequency range 1: 450MHz-6.0GHz, with a maximum channel bandwidth of 100 MHz. The Frequency range of the Frequency range 2 is 24.25GHz-52.6GHz, and the maximum channel bandwidth is 400 MHz. The near 11GHz spectrum for a 5G moving broadband comprises: 3.85GHz licensed spectrum, for example: 28GHz (24.25-29.5GHz), 37GHz (37.0-38.6GHz), 39GHz (38.6-40GHz) and 14GHz unlicensed spectrum (57-71 GHz). The working frequency bands of the 5G communication system comprise three frequency bands of 28GHz, 39GHz and 60 GHz.

In one embodiment, as shown in fig. 3-5, the plurality of slit cells 211 in each layer of the array structure 210 is a two-dimensional array, for example, may be a two-dimensional array of N × M (5 × 11). That is, the plurality of first slits 211a in each layer of the array structure 210 are also in a two-dimensional array. The array direction of the two-dimensional array includes a row direction and a column direction, and in the same array structure 210, the plurality of first slits 211a have gradually changed relative rotation angles in the row direction.

As shown in fig. 3, the first slits 211a in each layer of the array structure 210 are rectangular slits, and the second slits 211b are circular slits, and the rectangular slits are disposed in the circular slits, that is, the circular slits surround the rectangular slits. The rectangular gap and the circular gap are coaxially arranged, and the rectangular gap can rotate by taking the center of the circular gap as an axis.

As shown in fig. 4, the first slits 211a in each layer of the array structure 210 are oval slits, and the second slits 211b are square ring slits, and the oval slits are disposed in the square ring slits, that is, the square ring slits surround the oval slits. The oval gap and the square annular gap are coaxially arranged, and the oval gap can rotate by taking the center of the square annular gap as an axis.

In the present embodiment, the first slits 211a are rectangular slits, and the second slits 211b are all circular slits, for example.

In one embodiment, in the same array structure 210, the relative rotation angle of the first slits 211a in the row direction increases symmetrically from the first center line of the two-dimensional array to the edge of the array, and the relative rotation angle of the first slits 211a in the column direction is the same.

Specifically, the array centerlines in the two-dimensional array include a first centerline s1 and a second centerline s2, wherein the direction of the first centerline s1 is the same as the column direction and the direction of the second centerline s2 is the same as the row direction. Wherein the first slits 211a in each layer array structure 210 are symmetrically disposed about the first center line s1 and symmetrically disposed about the second center line s 2.

When the first slit 211a is a rectangular slit, the length direction and the column direction of the rectangular slit on the first central line are the same, the width direction and the row direction of the rectangular slit are the same, the length dimension of the rectangular slit is l, and the length dimension of the rectangular slit is w. When the first slit 211a is an elliptical slit, the major axis direction and the column direction of the elliptical slit located on the first central line are the same, the minor axis direction and the row direction are the same, the major axis dimension of the elliptical slit is l, and the minor axis dimension of the elliptical slit is w.

Each first slit 211a in each layer of array structure 210 has a relative rotation angle gradually changing with respect to the column direction (Y-axis) in the row direction, that is, each array unit 212 in the same row can rotate with respect to the Y-axis, and the relative rotation angle is a relative rotation angle. In the row direction, the relative rotation angle increases symmetrically from the first centerline s1 of the two-dimensional array to the array edge. It is understood that the relative rotation angles of all the first slits 211a of each column are the same, and the first slits 211a of the first to eleventh columns of each row are respectively rotated with respect to the Y axis. For example, the relative rotation angles of the first slits 211a of the sixth to eleventh columns of the third row may be represented by θ 1, θ 2, θ 3, θ 4, θ 5, and θ 6, respectively, where 0 ≦ θ 1< θ 2< θ 3< θ 4< θ 5< θ 6. In the present embodiment, the case where θ 1 is 0 is taken as an example, and in other embodiments, the value of θ 1 is not further limited.

In one embodiment, the slit units 211 in the array structure 210 are all arranged independently from each other, and the distance between the centers of two adjacent first slits 211a in the array direction is equal. Specifically, in the row direction, the first center distances p1 of two adjacent first slits 211a are equal; in the column direction, the second center distances p2 of two adjacent first slits 211a are equal. Wherein the first center distance p1 is equal to the second center distance p 2.

In the embodiment of the present application, the operating frequency band of the array lens may be adjusted by selecting an appropriate first center distance p1, second center distance p2P, and length and width dimensions of the first gap 211a, for example, by designing an appropriate size, the operating frequency band of the array lens may be maintained at a 5G millimeter wave frequency band, and the like.

When the array lens is applied to a lens antenna comprising a feed source array, the array structure 210 and the dielectric layer 220 in the array lens jointly form a phase delay unit, and when the plurality of first slits 211a in the same array structure 210 have a gradually-changed relative rotation angle relative to the array direction, a certain phase shift is generated, and the phase shift is positively correlated with the relative rotation angle. The phase shift amount achievable by the first slits 211a of each column satisfies Φ (x) ═ π x2/λ f. Where x is a distance between the center of the first slit 211a and the first center line s1, λ is a design frequency point (i.e., a transmission frequency of an electromagnetic wave transmitted by the feed array 30), and f is a distance between the array lens and the feed array (i.e., a focal length of the array lens).

The lens with symmetrical translation can be realized through the phase shift distribution, namely the phase shift distribution of different frequency bands can be compensated, so that electromagnetic waves radiated by the feed source array far away from the focus can be better converged in the row direction (X-axis direction) of the array lens, the amplitude reduction of the gain of a partial focus beam is greatly reduced, and the scanning angle of the lens antenna is greatly improved.

In one embodiment, as shown in fig. 5, the first slit 211a includes two rectangular slits arranged in parallel, wherein the length dimension l of the two rectangular slits in the parallel direction is different. For example, in the first slit 211a located on the first center line, the parallel direction of the two rectangular slits is the same as the column direction.

In one embodiment, as shown in fig. 6, the first slit 211a includes three rectangular slits arranged in parallel, wherein the length l of the three rectangular slits in the parallel direction is different. For example, in the first slit 211a located on the first center line, the parallel direction of the three rectangular slits is the same as the column direction.

In one embodiment, the first slits 211a may further include a plurality (greater than or equal to 2) of elliptical slits arranged in parallel, wherein major axes of the elliptical slits are arranged in parallel, and major axes of the elliptical slits have different sizes.

When the first slot 211a is a plurality of rectangular slots or elliptical slots with length and size, phase distribution of different frequency bands can be compensated, so that a focal plane of the array lens can be kept unchanged in a wider frequency range, electromagnetic waves radiated by the feed source array far away from a focal point can be better converged in the row direction (X-axis direction) of the array lens, the bandwidth of the lens antenna is improved, and the scanning angle of the lens antenna is greatly improved.

In one embodiment, as shown in fig. 7, the plurality of slit cells 211 in each layer of the array structure 210 is a two-dimensional array, for example, a two-dimensional array of N × M (5 × 11), that is, the slit cells 211 include N rows and M columns (5 rows and 11 columns). In the same array structure 210, the first slits 211a have gradually changed relative rotation angles in the row direction, and the first slits 211a have gradually changed relative rotation angles in the column direction.

In this embodiment, the first slit 211a is a rectangular slit, and the second slit 211b is a circular slit.

Specifically, the array centerlines in the two-dimensional array include a first centerline s1 and a second centerline s2, wherein the direction of the first centerline s1 is the same as the column direction and the direction of the second centerline s2 is the same as the row direction. Wherein the first slits 211a in each layer array structure 210 are symmetrically disposed about the first center line s1 and symmetrically disposed about the second center line s 2.

In each layer of array structure, the plurality of first slits 211a have relative rotation angles gradually changing with respect to the column direction (Y axis) in both the row direction and the column direction, that is, each array unit 212 in the same row may rotate with respect to the Y axis, and each array unit 212 in the same column may rotate with respect to the Y axis, where the relative rotation angle is the relative rotation angle.

In the row direction, the relative rotation angle increases symmetrically from the first centerline s1 of the two-dimensional array to the array edge. It is understood that the array units 212 of the first column to the eleventh column of each row are respectively rotated with respect to the Y-axis. For example, the relative rotation angles of the array units 212 of the sixth to eleventh columns of the third row may be represented by θ 1, θ 2, θ 3, θ 4, θ 5, and θ 6, respectively, where 0 ≦ θ 1< θ 2< θ 3< θ 4< θ 5< θ 6.

For example, the relative rotation angles of the array units 212 of the first to fifth rows of the sixth column may be represented by β 1, β, and β 3, respectively, where θ 1 is β and 0 ≦ β 1< β < β, respectively, in the embodiment of the present application, θ 1 is β is illustrated as 0, and in other embodiments, the value of θ 1 or β 1 is not further limited.

When the array unit 212 rotates about the X axis or the Y axis, the rotation direction may be clockwise or counterclockwise. Meanwhile, in the same array structure 210, the rotation directions of all the array units 212 are the same. In the embodiments of the present application, clockwise rotation is taken as an example for description. The difference between two adjacent relative rotation angles may be equal (e.g., 15 °, 30 °, etc.), may be an arithmetic number sequence, an geometric number sequence, or a random number, and in the embodiment of the present application, is not further limited.

In one embodiment, the slit units 211 in the array structure 210 are all arranged independently from each other, and the distance between the centers of two adjacent first slits 211a in the array direction is equal. Specifically, in the row direction, the first center distances p1 of two adjacent first slits 211a are equal; in the column direction, the second center distances p2 of two adjacent first slits 211a are equal. Wherein the first center distance p1 is equal to the second center distance p 2.

When the array lens is applied to a lens antenna comprising a feed source array, the array structure 210 and the dielectric layer 220 in the array lens jointly form a phase delay unit, and when the same array structure 210 has a gradually-changed relative rotation angle in the array direction relative to the first slot 211a located at the central line of the array, a plurality of first slots 211a generate a certain phase shift, and the phase shift is positively correlated with the relative rotation angle. The phase shift amount that can be achieved by the first slit 211a of each column (each column) satisfies Φ (x) ═ π x2/λ f. The amount of phase shift achievable by the first slot 211a per row (per column) satisfies Φ (x) ═ xy 2/λ f. Wherein y is the distance between the center of the first slit 211a and the second center line s2, λ is the design frequency point, and f is the distance between the array lens and the feed source array.

The lens with symmetrical translation can be realized by the phase shift distribution in the embodiment of the application, namely the phase distribution of different frequency bands can be compensated, so that electromagnetic waves radiated by the feed source array far away from the focus can be better converged in the row direction (X-axis direction) and the column direction (Y-axis direction) of the array lens, the amplitude reduction of the gain of the deflection beam is greatly reduced, and the scanning angle of the lens antenna is greatly improved.

In one embodiment, as shown in fig. 8, the plurality of slit cells 211 in each layer of the array structure 210 is a two-dimensional array, for example, a two-dimensional array of N × M (5 × 11), that is, the slit cells 211 include N rows and M columns (5 rows and 11 columns). In the same array structure 210, the plurality of first slits 211a have a gradually changing first slit size in at least one array direction.

The first slit dimension may be understood as a dimension of the first slit 211a located on the first center line s1 in the row direction, that is, a width dimension, and may also be understood as a dimension of the first slit 211a in the column direction, that is, a length dimension. In the embodiment of the present application, the first slit 211a is a rectangular slit, and the first slit dimension is a width dimension.

In the same array structure 210, the width dimension of the plurality of rectangular slits symmetrically decreases from the first center line s1 of the two-dimensional array to the edge of the array. For example, the width dimension of each rectangular slot in the third row is w, and the width dimension of each rectangular slot in the second row N3 and the fourth row is w 1; the width dimension of each rectangular slot in the first and fifth rows is w2, where w > w1> w 2.

In this embodiment, the relative rotation angles of the first slots 211a in the array direction are the same and the first slots have gradually changed slot sizes, so that phase distributions of different frequency bands can be compensated, and meanwhile, the converging effect on electromagnetic wave beams in the X-axis direction and the Y-axis direction can be realized, the bandwidth of the lens antenna is improved, and the scanning angle of the lens antenna is greatly improved.

In one embodiment, in the same array structure 210, the width dimension of the plurality of first slits 211a decreases symmetrically from the second center line s2 of the two-dimensional array to the edge of the array.

In one embodiment, in the same array structure 210, the width dimension of the plurality of first slits 211a decreases symmetrically from the first center line s1 of the two-dimensional array to the edge of the array, and the width dimension of the plurality of first slits 211a decreases symmetrically from the second center line s2 of the two-dimensional array to the edge of the array.

It should be noted that, in the embodiment of the present application, an embodiment in which the plurality of first slits 211a have the gradually-changed first slit size in at least one array direction may be arbitrarily combined with an embodiment in which the plurality of first slits 211a have the gradually-changed relative rotation angle with respect to the array direction in at least one array direction, and the combined embodiment is not repeated in this application.

In one embodiment, as shown in fig. 9, in the same array structure 210, a plurality of the first slits 211a have a relative rotation angle gradually changed with respect to at least one array direction. Meanwhile, the plurality of first slits 211a coaxially arranged in the multi-layer array structure 210 have a gradually changing first slit size in the first direction.

In one embodiment, the plurality of first slits 211a arranged coaxially have a gradually changing first slit size in the first direction. If the first slit 211a is a rectangular slit, the first slit dimension can be understood as the width dimension of the rectangular slit, or the length dimension of the first slit 211 a. If the first slit 211a is an elliptical slit, the first slit dimension may be understood as the minor axis dimension of the elliptical slit, or the major axis dimension of the elliptical slit.

In this embodiment, the first slit size is described as an example of the width size of a rectangular slit.

Referring to fig. 9, in one embodiment, the width of the rectangular slits in the array structure 210 in the same layer is the same, and the first slit size of the coaxially arranged first slits 211a decreases from the bottom layer to the top layer of the array lens. For example, the array lens 210 includes a 3-layer array structure P1-P3 and a 2-layer dielectric layer 220. The width dimension w1 of the first slit 211a in the array structure P1 is largest, the width dimension w2 of the first slit 211a in the array structure P2, the width dimension w3 of the first slit 211a in the array structure P3 decrease in sequence, and w1> w2> w 3.

In one embodiment, the width of the rectangular slits in the array structure 210 in the same layer is the same, and the first slit size of the coaxially arranged first slits 211a decreases symmetrically from the middle layer of the array lens to the top layer and the bottom layer of the array lens. For example, the array lens 210 includes a 3-layer array structure P1-P3 and a 2-layer dielectric layer 220. The width dimension w2 of the first slit 211a in the array structure P2 is largest, the width dimensions w1, w3 of the first slits 211a in the array structures P1, P3 are reduced relative to the width dimension w2 of the first slits 211a in the array structure P2, and w2> w3 ═ w 1.

In one embodiment, the width of the rectangular slits in the same layer of the array structure 210 is the same, and the first slit size of the coaxially disposed first slits 211a decreases from the top layer to the bottom layer of the array lens. For example, array lens 210 includes 3 layers of array structure 1-P3 and 2 layers of dielectric 220. The width dimension w3 of the first slit 211a in the array structure P3 is largest, the width dimension w2 of the first slit 211a in the array structure P2 and the width dimension w1 of the first slit 211a in the array structure P1 are successively decreased, and w3> w2> w 1.

It should be noted that, in the array lens, the plurality of first slits 211a coaxially disposed in the multi-layer array structure 210 have a gradually changing first slit size in the first direction, and meanwhile, the combination with any of the above embodiments may also be performed, which is not described herein.

The plurality of first slits 211a coaxially arranged in the array structure 210 in multiple layers in the array lens have gradually changed sizes of the first slits 211a in the first direction, so that phase distribution of different frequency bands can be compensated, meanwhile, the convergence effect on electromagnetic wave beams can be realized, the bandwidth of the lens antenna is improved, and the scanning angle of the lens antenna is greatly improved.

In one embodiment, the plurality of second slits 211b have a gradually changing second slit size in at least one array direction in the same array structure. Wherein the second slit size may be according to a loop width size of the second slit 211 b.

Specifically, in the same array structure, the second slit size of the plurality of second slits 211b decreases symmetrically from the first center line s1 of the two-dimensional array to the array edge in the row direction, or/and in the same array structure, the second slit size of the plurality of second slits 211b decreases symmetrically from the second center line s2 of the two-dimensional array to the array edge in the column direction.

The array lens in the embodiment can compensate the phase distribution of different frequency bands, and meanwhile, the convergence effect on electromagnetic wave beams can be realized, so that the bandwidth of the lens antenna is improved, and the scanning angle of the lens antenna is greatly improved.

The embodiment of the application also provides a lens antenna. As shown in fig. 10a, the lens antenna includes: the array lens 20 in any of the above embodiments, and the feed source array 30 arranged in parallel with the array lens 20.

In one embodiment, the feed array 30 includes a plurality of feed units 310, when different feed units 310 in the feed array 30 are fed, electromagnetic waves can enter the lens array lens 20 along the first direction, and the lens antenna radiates high-gain beams with different directions, that is, different beam directions can be obtained, thereby realizing beam scanning.

Further, the feed source array 30 may have a centrosymmetric structure, and the center of the feed source array 30 may be placed at the focal point of the lens array lens 20.

As shown in fig. 10b, in one embodiment, the lens antenna further includes a first isolation plate 410 and a second isolation plate 420 arranged in parallel, and the feed array 30 and the array lens 20 are arranged between the first isolation plate 410 and the second isolation plate 420, so as to reduce leakage of the feed array 30 radiating the electromagnetic wave.

Further, the plane of the feed array 30 is perpendicular to the plane of the first isolation plate 410, and the array direction of the feed array 30 is parallel to one array direction of the array unit 211. For example, the plurality of feed units 310 in the feed array 30 are linearly arranged along a second direction, which can be understood as a direction parallel to the X-axis as described with reference to fig. 10a, that is, the array direction of the feed array 30 is arranged parallel to the row direction of the array unit 211.

In one embodiment, the first isolation plate 410 and the second isolation plate 420 may be both flat metal plates.

In the present embodiment, by disposing the array lens 20 and the feed array 30 between the first isolation plate 410 and the second isolation plate 420, leakage of electromagnetic waves radiated from the feed source can be reduced, thereby improving the efficiency of the antenna and improving the structural strength of the antenna.

In one embodiment, the lens antenna further includes protective layers (not shown) attached to the side of the lens farthest from the feed array 30 and the side of the lens closest to the feed array 30.

The embodiment of the application also provides electronic equipment which comprises the lens antenna in any embodiment. The electronic device with the lens antenna of any embodiment can be suitable for receiving and transmitting 5G communication millimeter wave signals, and meanwhile, the lens antenna is short in focal length, small in size, easy to integrate into the electronic device and capable of reducing the occupied space of the lens antenna in the electronic device.

The electronic Device may be a communication module including a Mobile phone, a tablet computer, a notebook computer, a palm computer, a Mobile Internet Device (MID), a wearable Device (e.g., a smart watch, a smart bracelet, a pedometer, etc.), or other antenna.

In one embodiment, as shown in fig. 11, the electronic device further comprises a detection module 1110, a switch module 1120, and a control module 1130. The control module 1130 is connected to the detection module 1110 and the switch module 1120, respectively.

In one embodiment, the detection module 1110 can obtain the beam signal strength of the electromagnetic wave radiated by the lens antenna when each of the feed units 310 is in the working state. The detecting module 1110 may be further configured to detect and obtain parameters such as power of electromagnetic waves received by the lens antenna when each of the feed unit 310 is in an operating state, an electromagnetic wave Absorption ratio (SAR), or a Specific Absorption Rate (SAR).

In one embodiment, the switch module 1120 is connected to the feed array 30 for selectively connecting to any one of the feed units 310. In one embodiment, the switch module 1120 may include an input terminal connected to the control module 1130 and a plurality of output terminals connected to the plurality of feed source units 310 in a one-to-one correspondence. The switch module 1120 may be configured to receive a switching instruction sent by the control module 1130, so as to control on/off of each switch in the switch module 1120, and control on/off connection between the switch module 1120 and any one of the antenna feed source units 310, so that any one of the antenna feed source units 310 is in a working (on) state.

In one embodiment, the control module 1130 may control the switch module 1120 according to a preset strategy to respectively enable each feeding unit to be in a working state, so as to perform transceiving of electromagnetic waves, that is, to obtain different beam directions, thereby implementing beam scanning. When any feed unit 310 is in an operating state, the detection module 1110 may correspondingly obtain the beam signal strength of the electromagnetic wave radiated by the current lens antenna. Referring to fig. 12, a beam scanning pattern is obtained by simulation taking 7-element feed array 30 as an example. For example, when five feed source units 310 are included in the feed source array 30, the detection module 1110 may correspondingly obtain five beam signal strengths, and select the strongest beam signal strength from the five beam signal strengths, and use the feed source unit 310 corresponding to the strongest beam signal strength as the target feed source unit 310. Switching instructions from control module 1130 control the conductive connection between switch module 1120 and target feed unit 310 to place target feed unit 310 in an active (conductive) state.

The electronic device in this embodiment can obtain different beam directions by switching the switches to make each feed unit 310 of the feed array 30 individually in a working state, thereby implementing beam scanning without a shifter and an attenuator, and greatly reducing the cost.

As shown in fig. 13, in one embodiment, the electronic device 10 includes a plurality of lens antennas 20, and the plurality of lens antennas 20 are distributed on different sides of a frame of the electronic device. For example, the electronic device includes a plurality of lens antennas, the middle frame includes a first side 101 and a third side 103 that are opposite to each other, and a second side 102 and a fourth side 104 that are opposite to each other, the second side 102 is connected to one end of the first side 101 and the third side 103, and the fourth side 104 is connected to the other end of the first side 101 and the third side 103. And a plurality of the first side edge, the second side edge, the third side edge and the fourth side edge are respectively provided with a millimeter wave module.

In one embodiment, the two lens antennas are respectively arranged on two long sides of the mobile phone, so that the space on two sides of the mobile phone can be covered, and millimeter wave high-efficiency, high-gain and low-cost beam scanning of the 5G mobile phone is realized.

In one embodiment, when the number of lens antennas is 4, the 4 lens antennas are respectively located on the first side 101, the second side 102, the third side 103 and the fourth side 104. When the user holds the electronic device 10 by hand, the lens antenna can be shielded to cause the poor signal condition, the plurality of lens antennas are arranged on different sides, and when the user holds the electronic device 10 transversely or vertically, the lens antenna which is not shielded exists, so that the electronic device 10 can normally transmit and receive signals.

Any reference to memory, storage, database, or other medium used herein may include non-volatile and/or volatile memory. Suitable non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM), which acts as external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms, such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), double data rate SDRAM (DDR SDRAM), Enhanced SDRAM (ESDRAM), synchronous Link (Synchlink) DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and bus dynamic RAM (RDRAM).

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.