Patent Description:
In a wireless local area network (wireless local area network, WLAN) service, more antennas may be integrated into an access point (access point, AP) to improve signal bandwidth of the AP. A vertical polarization antenna and a horizontal polarization antenna may be placed on the AP in a stacked manner, to reduce a size of the AP. An antenna is required to have strong radiation at a large angle and have a far-region coverage capability, to ensure a signal coverage distance of the AP.

Limited by an AP thickness, a spacing between the horizontal polarization antenna and the vertical polarization antenna is small, and coupling is strong. It represents that the horizontal polarization antenna above the vertical polarization antenna affects radiation of the vertical polarization antenna below. This reduces a maximum radiation angle of the vertical polarization antenna, and shortens a coverage distance of the vertical polarization antenna. That is, that the horizontal polarization antenna blocks the vertical polarization antenna deteriorates radiation performance of the vertical polarization antenna.

<CIT> provides an antenna system includes a system ground plane, a first antenna array, and a second antenna array. The second antenna array is disposed between the first antenna array and the system ground plane. The first antenna array has a first polarization direction. The second antenna array has a second polarization direction. The first polarization direction and the second polarization direction are orthogonal to each other.

<CIT> relates to a dual-polarization antenna, and more particularly to a dual-polarization antenna and an array antenna suitable for a dual-polarization mobile communication base station antenna or the like that requires a high gain.

<NPL> provides a circular-polarised antenna with omni-directional radiation. The antenna consists of four bended dipoles, excited simultaneously by integrated baluns.

<CIT> relates to a printed dipole oscillator, comprising a dielectric plate, and further comprising a feed portion disposed in the middle of the dielectric plate, and a plurality of dipole units arranged on the dielectric plate around the feed portion. Each dipole unit comprises a front-surface oscillator arm and a back-surface oscillator arm respectively disposed on the front surface and the back surface of the dielectric plate. The feed portion feeds the front-surface oscillator arm and the back-surface oscillator arm.

<CIT> provides an antenna device includes antenna units, transmission lines and switching circuits. The antenna units are used to be operated in a directional mode or an omnidirectional mode. The transmission lines are coupled to the antenna units. The switching circuits are coupled to the respective transmission lines, and are used for selectively connecting the transmission lines according to control signals. At least one transmission line is disconnected when the antenna units are operated in the directional mode. All the transmission lines are connected when the antenna units are operated in the omni-directional mode.

<CIT> discloses a super-wide band high-gain dual-polarization omnidirectional antenna.

<NPL> discloses tightly coupled array of horizontal dipoles over a ground plane.

This application provides an antenna and a communications device, to resolve a problem that radiation performance of a vertical polarization antenna deteriorates due to a blocking problem. According to a first aspect, an antenna as defined in claim <NUM> is provided. The antenna comprises a horizontal polarization antenna (<NUM>) and a vertical polarization antenna (<NUM>) that are disposed in a stacked manner. The horizontal polarization antenna includes a radiation element and a double-sided parallel strip line (double-sided parallel strip line, DSPSL). One end of the double-sided parallel strip line is connected to the radiation element. A length range of the double-sided parallel strip line is <NUM> to <NUM> times a waveguide wavelength of an electromagnetic wave in the double-sided parallel strip line at an operating frequency of the vertical polarization antenna.

In this application, when the vertical polarization antenna works, radiant energy of the vertical polarization antenna is coupled to the horizontal polarization antenna, and is transmitted to the radiation element through the double-sided parallel strip line for radiation (in this application, a field in which the energy obtained by the horizontal polarization antenna from the vertical polarization antenna through coupling is radiated is referred to as a coupling radiation field of the horizontal polarization antenna). In this case, distribution of a total radiation field of the vertical polarization antenna is affected by the coupling radiation field of the horizontal polarization antenna. In this application, the total radiation field of the vertical polarization antenna refers to a radiation field as interference result of the coupling radiation field of the horizontal polarization antenna and a radiation field of the vertical polarization antenna. A total phase delay of the double-sided parallel strip line is changed by adjusting a length of the double-sided parallel strip line, to adjust a phase of the coupling radiation field of the horizontal polarization antenna. The total radiation field of the vertical polarization antenna is changed (that is, an intervention mode of the coupling radiation field of the horizontal polarization antenna and the radiation field of the vertical polarization antenna is changed), to achieve a purpose of adjusting a radiation angle of the vertical polarization antenna to enhance a large-angle radiation capability of the vertical polarization antenna. According to the solutions provided in this application, deterioration of radiation performance of the vertical polarization antenna caused by a blocking problem is alleviated without increasing an overall height of the antenna.

The double-sided parallel strip line is not linear.

A linear distance between the radiation element and the other end of the double-sided parallel strip line is <NUM> to <NUM> times the waveguide wavelength. For example, if an operating frequency of the vertical polarization antenna is <NUM> gigahertz (GHz), a dielectric constant of a material inside the double-sided parallel strip line is <NUM>, and a thickness of the material is <NUM> millimeter, the linear distance between the radiation element and the other end of the double-sided parallel strip line ranges from <NUM> millimeters to <NUM> millimeters.

In this application, the double-sided parallel strip line is designed to be non-linear, so that an area of the horizontal polarization antenna in a horizontal direction can be reduced while a length requirement of the double-sided parallel strip line is met, thereby reducing a volume of the antenna. Optionally, the double-sided parallel strip line includes a bend line structure and/or a bent line structure.

Optionally, an operating frequency band of the vertical polarization antenna is the same as an operating frequency band of the horizontal polarization antenna. In this application, the operating frequency of the vertical polarization antenna is the same as or close to an operating frequency of the horizontal polarization antenna.

Optionally, line widths of the double-sided parallel strip line are not all equal, that is, the double-sided parallel strip line is of an unequal-line-width structure.

In this application, impedance matching of the horizontal polarization antenna can be implemented by designing unequal line widths of the double-sided parallel strip line.

Optionally, the radiation element is a dipole element. For example, the radiation element is a double-sided printed dipole element.

Optionally, the vertical polarization antenna is a monopole antenna.

Optionally, the horizontal polarization antenna further includes a substrate. Both the double-sided parallel strip line and the radiation element are disposed on the substrate.

Optionally, the antenna further includes a ground plate. The vertical polarization antenna is disposed on the ground plate, and the horizontal polarization antenna is disposed on a side that is of the vertical polarization antenna and that is away from the ground plate.

According to a second aspect, a communications device is provided. The communications device includes a radio frequency circuit and the antenna according to any one of the first aspect. The radio frequency circuit is connected to the antenna.

The technical solutions provided in this application have at least the following beneficial effects. The antenna provided in this application includes a horizontal polarization antenna and a vertical polarization antenna that are disposed in a stacked manner. A length of a double-sided parallel strip line is <NUM> to <NUM> times a waveguide wavelength of an electromagnetic wave in the double-sided parallel strip line at an operating frequency of the vertical polarization antenna. When the vertical polarization antenna works, distribution of a total radiation field of the vertical polarization antenna is affected by a coupling radiation field of the horizontal polarization antenna. A total phase delay of the double-sided parallel strip line is changed by adjusting the length of the double-sided parallel strip line, to adjust a phase of the coupling radiation field of the horizontal polarization antenna. The total radiation field of the vertical polarization antenna is changed, that is, an intervention mode of the coupling radiation field of the horizontal polarization antenna and a radiation field of the vertical polarization antenna is changed, to achieve a purpose of adjusting a radiation angle of the vertical polarization antenna to enhance a large-angle radiation capability of the vertical polarization antenna. According to the solutions provided in this application, deterioration of radiation performance of the vertical polarization antenna caused by a blocking problem is alleviated without increasing an overall height of the antenna. This increases a gain of the vertical polarization antenna on a large-angle pitch plane, and enhances a far-region radiation capability of the vertical polarization antenna. In this way, a compact design of a product can be realized without increasing a thickness of the communications device. In addition, a far-region radiation capability of an antenna is improved, so that a signal coverage area of the communications device can be expanded. In this way, deployment density of the communications device, a quantity of deployed communications devices, and costs can be reduced.

To make the objectives, technical solutions, and advantages of this application clearer, the following further describes an antenna and a communications device provided in embodiments of this application in detail with reference to the accompanying drawings.

<FIG> is a schematic structural diagram of an antenna according to an embodiment of this application. As shown in <FIG>, the antenna includes a horizontal polarization antenna <NUM> and a vertical polarization antenna <NUM> that are disposed in a stacked manner. <FIG> is a schematic structural diagram of a horizontal polarization antenna according to an embodiment of this application. As shown in <FIG>, the horizontal polarization antenna <NUM> includes a radiation element <NUM> and a double-sided parallel strip line <NUM>. One end of the double-sided parallel strip line <NUM> is connected to the radiation element <NUM>.

A length range of the double-sided parallel strip line <NUM> is <NUM> to <NUM> times a waveguide wavelength of an electromagnetic wave in the double-sided parallel strip line <NUM> at an operating frequency of the vertical polarization antenna <NUM>.

The waveguide wavelength is a wavelength at which the electromagnetic wave is transmitted in the double-sided parallel strip line <NUM> at the operating frequency of the vertical polarization antenna <NUM>. The waveguide wavelength is correlated with the operating frequency, a size of the double-sided parallel strip line, and a dielectric constant and a thickness of a material inside the double-sided parallel strip line. A length of the double-sided parallel strip line adjusts one waveguide wavelength, and a corresponding phase variation is <NUM>°.

Optionally, referring to <FIG>, the horizontal polarization antenna <NUM> further includes a substrate <NUM>. The radiation element <NUM> and the double-sided parallel strip line <NUM> are both disposed on the substrate <NUM>. The material inside the double-sided parallel strip line <NUM> is a material of the substrate <NUM>. The substrate may be a printed circuit board (printed circuit board, PCB). For example, the operating frequency of the vertical polarization antenna <NUM> is <NUM>, a dielectric constant of the substrate <NUM> is <NUM>, and a thickness of the substrate <NUM> is <NUM> millimeter. In this case, the waveguide wavelength of the electromagnetic wave in the double-sided parallel strip line <NUM> is <NUM> millimeters. The length range of the double-sided parallel strip line <NUM> is <NUM> millimeters to <NUM> millimeters. Optionally, the substrate <NUM> is an epoxy resin board.

In conclusion, the embodiments of this application provide the antenna. The antenna includes the horizontal polarization antenna and the vertical polarization antenna that are disposed in the stacked manner. The length of the double-sided parallel strip line is <NUM> to <NUM> times the waveguide wavelength of the electromagnetic wave in the double-sided parallel strip line at the operating frequency of the vertical polarization antenna. When the vertical polarization antenna works, distribution of a radiation field of the vertical polarization antenna is affected by a coupling radiation field of the horizontal polarization antenna. A total phase delay of the double-sided parallel strip line of the horizontal polarization antenna is changed by adjusting the length of the double-sided parallel strip line, to adjust a phase of the coupling radiation field of the horizontal polarization antenna. The total radiation field of the vertical polarization antenna is changed, that is, an intervention mode of the coupling radiation field of the horizontal polarization antenna and the radiation field of the vertical polarization antenna is changed, to achieve a purpose of adjusting a radiation angle of the vertical polarization antenna to enhance a large-angle radiation capability of the vertical polarization antenna. According to the solutions provided in this application, deterioration of radiation performance of the vertical polarization antenna caused by a blocking problem can be alleviated without increasing an overall height of the antenna.

The horizontal polarization antenna <NUM> has two opposite sides, which are respectively a first side away from the vertical polarization antenna and a second side close to the vertical polarization antenna. <FIG> is a top view of a first side of a horizontal polarization antenna according to an embodiment of this application. <FIG> is a top view of a second side of a horizontal polarization antenna according to an embodiment of this application. Referring to <FIG>, <FIG>, the radiation element <NUM> is a double-sided printed radiation element. The radiation element <NUM> includes a first arm <NUM> located on a first side of the substrate <NUM> and a second arm <NUM> located on a second side of the substrate <NUM>. The double-sided parallel strip line <NUM> includes a first conductor <NUM> located on the first side of the substrate <NUM> and a second conductor <NUM> located on the second side of the substrate <NUM>. The first conductor <NUM> and the second conductor <NUM> have a same shape and a same line width. To be specific, an orthographic projection of the first conductor <NUM> on the substrate <NUM> fully coincides with an orthographic projection of the second conductor <NUM> on the substrate <NUM>. The first arm <NUM> is connected to the first conductor <NUM>, and the second arm <NUM> is connected to the second conductor <NUM>.

In the embodiment of this application, the horizontal polarization antenna includes one radiation element and one double-sided parallel strip line, or the horizontal polarization antenna includes a plurality of radiation elements and a plurality of double-sided parallel strip lines. A quantity of radiation elements is the same as a quantity of double-sided parallel strip lines. Each double-sided parallel strip line is connected to one radiation element. For example, referring to <FIG>, the horizontal polarization antenna <NUM> includes four radiation elements <NUM> and four double-sided parallel strip lines <NUM>.

Optionally, referring to <FIG>, the horizontal polarization antenna <NUM> further includes a feedpoint <NUM>. One end of the double-sided parallel strip line <NUM> is connected to the radiation element <NUM>, and the other end is connected to the feedpoint <NUM>. The feedpoint <NUM> feeds the first arm <NUM> in the radiation element <NUM> through the first conductor <NUM> in the double-sided parallel strip line <NUM>, and feeds the second arm <NUM> in the radiation element <NUM> through the second conductor <NUM> in the double-sided parallel strip line <NUM>.

Optionally, when the horizontal polarization antenna includes the plurality of radiation elements and the plurality of double-sided parallel strip lines, the plurality of radiation elements are disposed axisymmetrically or centrosymmetrically, and the plurality of double-sided parallel strip lines are connected to one feedpoint. For example, referring to <FIG>, the four radiation elements <NUM> in the horizontal polarization antenna <NUM> are disposed centrosymmetrically, and the feedpoint <NUM> is located in a symmetric center of the four radiation elements <NUM>. The feedpoint may also be referred to as a central feedpoint. Optionally, the feedpoint is a metal patch. The feedpoint may be in a circular shape, a rectangular shape, or the like.

In the embodiment of this application, the horizontal polarization antenna may be fed by using a coaxial cable, and the coaxial cable (not shown in the figure) is connected to the feedpoint. If the quantity of radiation elements included in the horizontal polarization antenna is N, and N is an integer greater than <NUM>, the horizontal polarization antenna may also be referred to as an N-element antenna. Correspondingly, the horizontal polarization antenna includes N double-sided parallel strip lines, and the N double-sided parallel strip lines and the feedpoint form a feeding network, to transfer energy transmitted by the coaxial cable to the N radiation elements. Therefore, the N radiation elements can be fed. The feedpoint is connected to a one-to-N power splitter. The one-to-N power splitter can divide the energy transmitted by the coaxial cable into N paths, and respectively transmit the N paths of energy to the N double-sided parallel strip lines through the feedpoint.

Referring to <FIG>, the double-sided parallel strip line <NUM> is not linear. That is, a length of the double-sided parallel strip line <NUM> is greater than a distance between the radiation element <NUM> and the feedpoint <NUM>. A linear distance (that is, a linear distance between the radiation element <NUM> and the feedpoint <NUM>) between the radiation element <NUM> and the other end of the double-sided parallel strip line <NUM> is <NUM> to <NUM> times the waveguide wavelength. For example, if an operating frequency of the vertical polarization antenna <NUM> is <NUM>, a dielectric constant of a material inside the double-sided parallel strip line <NUM> is <NUM>, and a thickness of the material is <NUM> millimeter, the linear distance between the radiation element <NUM> and the other end of the double-sided parallel strip line <NUM> ranges from <NUM> millimeters to <NUM> millimeters.

Optionally, the double-sided parallel strip line includes a bend line structure and/or a bent line structure. For example, <FIG> is a schematic structural diagram of a double-sided parallel strip line according to an embodiment of this application. As shown in <FIG>, the double-sided parallel strip line <NUM> is of a sawtooth-shaped bend line structure. Alternatively, as shown in <FIG>, the double-sided parallel strip line <NUM> is of a square-shape bend line structure. Alternatively, as shown in <FIG>, the double-sided parallel strip line <NUM> is of a bent line structure. The structures of the double-sided parallel strip line in <FIG> are merely used for illustration. A shape of the double-sided parallel strip line is not limited in the embodiments of this application. Referring to <FIG>, the double-sided parallel strip line <NUM> is the square-shape bend line structure. For example, a length of the double-sided parallel strip line <NUM> is <NUM> millimeters. Referring to <FIG>, a distance d between the radiation element <NUM> and the feedpoint <NUM> is <NUM> millimeters. A length w1 of a first bent section of the double-sided parallel strip line <NUM> is <NUM> millimeters, a length w2 of a second bent section is <NUM> millimeters, and a length w3 of a third bent section is <NUM> millimeters.

In this embodiment of this application, the double-sided parallel strip line is designed to be non-linear, so that an area of the horizontal polarization antenna in a horizontal direction can be reduced while a length requirement of the double-sided parallel strip line is met, thereby reducing a volume of the antenna.

Alternatively, the double-sided parallel strip line <NUM> may be linear. This is not limited in the embodiments of this application.

Optionally, the double-sided parallel strip line has unequal line widths, that is, the line widths of the double-sided parallel strip line are not all equal. For example, line widths of two ends of the double-sided parallel strip line are less than line widths of a middle part of the double-sided parallel strip line. Impedance matching of the horizontal polarization antenna can be implemented by designing the unequal line widths of the double-sided parallel strip line.

Optionally, the radiation element in the horizontal polarization antenna is a dipole element. Referring to <FIG>, the first arm <NUM> and the second arm <NUM> included in the dipole element <NUM> are arranged symmetrically around an axis of the double-sided parallel strip line <NUM>. That is, an extension direction of the first arm <NUM> is opposite to an extension direction of the second arm <NUM>.

Alternatively, the radiation element in the horizontal polarization antenna may be another type of radiation element, for example, may be a slot radiation element. In this case, the horizontal polarization antenna is a slot antenna.

Optionally, the vertical polarization antenna is a monopole antenna. An operating frequency band of the vertical polarization antenna may be the same as an operating frequency band of the horizontal polarization antenna. For example, operating frequency bands of both the vertical polarization antenna and the horizontal polarization antenna may be <NUM> frequency bands. Optionally, <FIG> is a schematic structural diagram of another horizontal polarization antenna according to an embodiment of this application. As shown in <FIG>, the horizontal polarization antenna <NUM> further includes a plurality of directors <NUM> and a plurality of reflectors <NUM>. The plurality of directors <NUM> and the plurality of reflectors <NUM> are all located on a first side of the substrate <NUM>, and are evenly arranged around the radiation element <NUM>. For example, <FIG> shows that the horizontal polarization antenna includes <NUM> directors <NUM> and <NUM> reflectors <NUM>. Optionally, referring to <FIG>, the antenna further includes a ground plate <NUM>. The vertical polarization antenna <NUM> is disposed on the ground plate <NUM>, and the horizontal polarization antenna <NUM> is disposed on a side that is of the vertical polarization antenna <NUM> and that is away from the ground plate <NUM>. The ground plate <NUM> may be a metal plate.

In the embodiments of this application, simulation is further separately performed on a vertical polarization antenna, a vertical polarization antenna and a conventional horizontal polarization antenna that are disposed in a stacked manner, and the antenna provided in the embodiments of this application. Simulation results are as follows:
<FIG> shows an antenna in a related technology and a simulated radiation pattern obtained through simulation. <FIG> shows another antenna in a related technology and a radiation field pattern obtained through simulation. <FIG> shows an antenna and a radiation field pattern obtained through simulation according to an embodiment of this application. In <FIG>, <FIG>, and <FIG>, left diagrams are schematic structural diagrams of antennas, and right diagrams are simulated radiation patterns corresponding to the antennas shown in the left diagrams. The antennas shown in <FIG> each include a ground plate D. The simulated radiation pattern represents a radiation field of the antenna on a cross section perpendicular to the ground plate D. An arrow in the figure points to a direction that is perpendicular to the ground plate D and that is away from the ground plate D. Due to a reflection effect of the ground plate D, most of radiant energy of the antenna ranges from -<NUM>° to +<NUM>°.

As shown in <FIG>, the antenna includes a vertical polarization antenna V disposed on the ground plate D. A maximum gain direction of the vertical polarization antenna V is <NUM>°.

As shown in <FIG>, the antenna includes the vertical polarization antenna V and a conventional horizontal polarization antenna H1 that are disposed on the ground plate D in a stacked manner. Affected by coupling of the conventional horizontal polarization antenna H1, a maximum gain radiation angle of the vertical polarization antenna V shrinks to <NUM>°, and a maximum gain direction is <NUM>°. It can be learned through comparison of <FIG> and <FIG> that the conventional horizontal polarization antenna causes reduction of a gain of the vertical polarization antenna that is at a large angle (for example, <NUM>°). Consequently, a coverage distance of the vertical polarization antenna reduces.

As shown in <FIG>, the antenna includes the vertical polarization antenna V and a horizontal polarization antenna H2 that are disposed on the ground plate D in a stacked manner. The horizontal polarization antenna H2 may be the horizontal polarization antenna <NUM> shown in <FIG>. A phase of a coupling radiation field of the horizontal polarization antenna is adjusted by bending a double-sided parallel strip line of the horizontal polarization antenna H2, so that a maximum gain radiation angle of the vertical polarization antenna changes to a large angle. A maximum gain direction of the vertical polarization antenna is <NUM>°, which exceeds the maximum gain direction <NUM>° in <FIG> and also exceeds the maximum gain direction <NUM>° in <FIG>. That is, after the horizontal polarization antenna H2 is stacked, the vertical polarization antenna V has a higher gain and a longer coverage distance at a large angle.

Radiation fields in <FIG> and <FIG> are radiation fields of the vertical polarization antenna V, and the radiation fields are obtained through simulation when the horizontal polarization antenna does not work. An operating frequency of the vertical polarization antenna V is <NUM>, a dielectric constant of a material inside double-sided parallel strip lines of the horizontal polarization antenna H1 and the horizontal polarization antenna H2 is <NUM>, and a thickness of the material is <NUM> millimeter. A length of the double-sided parallel strip line in the horizontal polarization antenna H1 in <FIG> is <NUM> millimeters (that is, at the operating frequency of <NUM>, the length of the double-sided parallel strip line is <NUM> times a waveguide wavelength of an electromagnetic wave in the double-sided parallel strip line). A length of the double-sided parallel strip line in the horizontal polarization antenna H2 in <FIG> is <NUM> millimeters (that is, <NUM> times a waveguide wavelength of an electromagnetic wave in the double-sided parallel strip line at the operating frequency of <NUM>).

It can be learned through comparison of <FIG> and <FIG> that in <FIG>, after the conventional horizontal polarization antenna H1 is stacked on the vertical polarization antenna V, a radiation field pattern of the vertical polarization antenna V shrinks, that is, a signal coverage area of the vertical polarization antenna V becomes smaller. It can be learned through comparison of <FIG> and <FIG> that in <FIG>, after the horizontal polarization antenna H2 provided in the embodiments of this application is stacked on the vertical polarization antenna V, the radiation field pattern of the vertical polarization antenna V expands, that is, the signal coverage area of the vertical polarization antenna V becomes larger. Therefore, the antenna provided in this embodiment of this application improves a far-region radiation capability of the vertical polarization antenna.

For example, <FIG> is a schematic diagram of field distribution of a <NUM>° tangent plane of radiation field patterns of the vertical polarization antenna V in <FIG>, the vertical polarization antenna V in the antenna V+H1 in <FIG>, and the vertical polarization antenna V in the antenna V+H2 in <FIG>. The <NUM>° tangent plane is a <NUM>° pitch plane of the antenna. Table <NUM> lists average gains (unit: decibel (dB)) of the three antennas on the <NUM>° pitch plane.

Referring to Table <NUM>, the average gain of the vertical polarization antenna V in <FIG> on the <NUM>° pitch plane is less than the average gain of the vertical polarization antenna V in <FIG> on the <NUM>° pitch plane. The average gain of the vertical polarization antenna V in <FIG> on the <NUM>° pitch plane is greater than the average gain of the vertical polarization antenna V in <FIG> on the <NUM>° pitch plane. It can be learned from Table <NUM> and <FIG> that the antenna provided in the embodiments of this application can increase a gain of the vertical polarization antenna on a large-angle pitch plane.

In conclusion, the embodiments of this application provide the antenna. The antenna includes the horizontal polarization antenna and the vertical polarization antenna that are disposed in the stacked manner. A length of a double-sided parallel strip line is <NUM> to <NUM> times a waveguide wavelength of an electromagnetic wave in the double-sided parallel strip line at the operating frequency of the vertical polarization antenna. When the vertical polarization antenna works, distribution of a total radiation field of the vertical polarization antenna is affected by a coupling radiation field of the horizontal polarization antenna. A total phase delay of the double-sided parallel strip line is changed by adjusting the length of the double-sided parallel strip line, to adjust a phase of the coupling radiation field of the horizontal polarization antenna. To be specific, the total radiation field of the vertical polarization antenna is changed, to achieve a purpose of adjusting a radiation angle of the vertical polarization antenna to enhance a large-angle radiation capability of the vertical polarization antenna. According to the solutions provided in this application, deterioration of radiation performance of the vertical polarization antenna caused by a blocking problem is alleviated without increasing an overall height of the antenna. This increases a gain of the vertical polarization antenna on the large-angle pitch plane, and enhances a far-region radiation capability of the vertical polarization antenna.

<FIG> is a schematic structural diagram of a communications device according to an embodiment of this application. As shown in <FIG>, the communications device includes an antenna <NUM> and a radio frequency circuit <NUM>. The antenna <NUM> may be the antenna shown in <FIG>. The antenna <NUM> includes the vertical polarization antenna <NUM> and the horizontal polarization antenna <NUM> shown in any one of <FIG>, and <FIG>. The antenna <NUM> is connected to the radio frequency circuit <NUM>.

Optionally, the antenna <NUM> is connected to the radio frequency circuit <NUM> through a coaxial cable. Referring to <FIG>, the radio frequency circuit <NUM> is connected to the horizontal polarization antenna <NUM> through the coaxial cable L1. For example, one end of the coaxial cable L1 is connected to a feedpoint <NUM> of the horizontal polarization antenna <NUM>, and the other end of the coaxial cable L1 is bent to a surface of a ground plate <NUM>. The other end of the coaxial cable L1 extends along the surface of the ground plate <NUM> and is connected to the radio frequency circuit <NUM>.

In this embodiment of this application, the vertical polarization antenna <NUM> is also connected to the radio frequency circuit <NUM>. For example, referring to <FIG>, the radio frequency circuit <NUM> is connected to the vertical polarization antenna <NUM> through a coaxial cable L2. Alternatively, the antenna <NUM> may further include a transmission line printed on the ground plate <NUM>, and the vertical polarization antenna <NUM> is connected to the radio frequency circuit <NUM> through the transmission line.

Optionally, the communications device is an AP or a base station.

In conclusion, an embodiment of this application provides a communications device, and the communications device includes an antenna. According to the solutions provided in the embodiments of this application, deterioration of radiation performance of the vertical polarization antenna caused by a blocking problem can be alleviated without increasing an overall height of the antenna. Therefore, a compact design of a product can be realized without increasing a thickness of the communications device. In addition, in the antenna provided in the embodiments of this application, a gain of the vertical polarization antenna on a large-angle pitch plane is increased, and a far-region radiation capability of the vertical polarization antenna is enhanced. Therefore, signal strength of the communications device can be increased, and a signal coverage area of the communications device can be expanded. In this way, deployment density of the communications device, a quantity of deployed communications devices, and costs can be reduced. In the embodiments of this application, the terms "first", "second", and "third" are merely used for a purpose of description, and shall not be understood as an indication or implication of relative importance.

The term "and/or" in this application describes only an association relationship for describing associated objects and represents that three relationships may exist.

Claim 1:
An antenna, comprising a horizontal polarization antenna (<NUM>) and a vertical polarization antenna (<NUM>) that are disposed in a stacked manner, wherein the horizontal polarization antenna (<NUM>) comprises a radiation element (<NUM>) and a double-sided parallel strip line (<NUM>), one end of the double-sided parallel strip line (<NUM>) is connected to the radiation element (<NUM>), and
a length range of the double-sided parallel strip line (<NUM>) is <NUM> to <NUM> times a waveguide wavelength of an electromagnetic wave in the double-sided parallel strip line at an operating frequency of the vertical polarization antenna (<NUM>);
wherein the antenna further comprises a ground plate (<NUM>), the vertical polarization antenna (<NUM>) is disposed on the ground plate, and the horizontal polarization antenna (<NUM>) is disposed on a side that is of the vertical polarization antenna (<NUM>) and that is away from the ground plate (<NUM>);
wherein the double-sided parallel strip line (<NUM>) is not linear;
wherein a linear distance between the radiation element and the other end of the double-sided parallel strip line is <NUM> to <NUM> times the waveguide wavelength.