KR20180017626A - Antenna device for base station and base station having the same - Google Patents

Abstract

Disclosed are a base station antenna device and a base station including the same. According to an embodiment, the base station antenna device includes: a first-1 polarization antenna group including a plurality of antennas prepared to have first polarization; a first-2 polarization antenna group including a plurality of antennas prepared to have a first polarization, and placed at a distance from the first-1 polarization antenna group; a second-1 polarization antenna group including a plurality of antennas prepared to have a second polarization; a second-2 polarization antenna group including a plurality of antennas prepared to have a second polarization, and placed at a distance from the second-1 polarization antenna group; a first phase difference generating part making a difference in the directivity of a beam by generating a phase difference between the first-1 polarization antenna group and first-2 polarization antenna group; and a second phase difference generating part making a difference in the directivity of a beam by generating a phase difference between the second-1 polarization antenna group and second-2 polarization antenna group.

Description

[0001] The present invention relates to a base station antenna apparatus and a base station including the base station antenna apparatus.

Embodiments of the invention relate to base station antenna technology.

Generally, a base station antenna apparatus is composed of antennas having different polarization characteristics, and is provided to transmit only two beams having polarization characteristics different from each other by having one input port for each polarization characteristic. However, in this case, there is a problem that the communication area that can be covered by the base station can be limited.

Korean Patent Registration No. 10-1596922 (Feb. Korean Patent Publication No. 10-2010-0134552 (December 23, 2010)

An embodiment of the present invention is to provide a base station antenna device capable of extending communication coverage and a base station including the same.

An embodiment of the present invention is to provide a base station antenna apparatus and a base station including the base station antenna apparatus capable of expanding space availability.

A base station antenna apparatus according to an embodiment of the present invention includes: a 1-1 polarization antenna group including a plurality of antennas provided with a first polarization; A 1-2 polarization antenna group including a plurality of antennas provided to have the first polarized wave and being spaced apart from the 1-1 polarized antenna group; A 2-1 polarization antenna group including a plurality of antennas arranged to have a second polarization; A second 2-polarized antenna group including a plurality of antennas provided to have the second polarized wave, the second 2-polarized antenna group being spaced apart from the 2-1 polarized antenna group; A first phase difference generator for generating a phase difference between the first 1-1 polarization antenna group and the 1-2 polarization antenna group so that beam directivity is differently formed; And a second phase difference generator for generating a phase difference between the 2-1 polarized antenna group and the 2-2 polarized antenna group so that the directivity of the beam is formed differently.

Wherein the first phase difference generator is configured to generate a phase difference of 90 ° between the first 1-1 polarization antenna group and the 1-2 polarization antenna group, And a phase difference of 90 ° may be generated between the second -2 polarized antenna groups.

Wherein the first phase difference generator includes a first input port and a second input port to which a feed current is input and a first output port and a second output port through which a feed current having a phase difference of 90 ° with respect to each other is output, Wherein the second phase difference generator includes a third input port and a fourth input port to which a feed current is input and a third output port and a fourth output port through which a feed current having a phase difference of 90 ° with respect to each other is output, A first power divider connected to a first output port of the first phase difference generator and supplying a power supply current output from the first output port to each antenna of the first polarization antenna group; A second power divider connected to a second output port of the first phase difference generator and supplying a feed current output from the second output port to each antenna of the first and second polarization antenna groups; A third power divider connected to a third output port of the second phase difference generator and supplying a feed current output from the third output port to each antenna of the second -1 polarization antenna group; And a fourth power divider connected to a fourth output port of the second phase difference generator and supplying a feed current output from the fourth output port to each antenna of the second -2 polarization antenna group .

Wherein the first output port of the first phase difference generator outputs a feed current of + 45 ° phase, the second output port of the first phase difference generator outputs a feed current of -45 ° phase, and the second phase port of the second phase difference generator The third output port outputs a feed current of -45 ° and the fourth output port of the second phase difference generator outputs a feed current of -135 ° phase.

Wherein the first phase difference generator is provided with a plurality of antennas corresponding to the antennas included in the first 1-1 polarization antenna group and the first 1-2 polarization antenna group, A plurality of first phase difference generating units are provided corresponding to the respective antennas included in the polarized antenna group and the second -2 polarized wave antenna group and each of the plurality of first phase difference generating units includes a first input port, And a second output port, and the plurality of second phase difference generators each include a third input port, a fourth input port, a third output port, and a fourth output port, A first power divider for supplying the input power supply current to the first input port of the plurality of first phase difference generators; A second power divider for supplying the input power supply current to a second input port of the plurality of first phase difference generators; A third power divider that supplies the input power supply current to a third input port of the plurality of second phase difference generators; And a fourth power divider that supplies the input power supply current to a fourth input port of the plurality of second phase difference generators.

The first output ports of the plurality of first phase difference generators are respectively connected to the antennas of the first 1-1 polarization antenna group and the second output ports of the plurality of first phase difference generators are connected to the first 1-2 second polarity antenna group The third output port of the plurality of second phase difference generators is connected to the antennas of the second-1 polarized antenna group, and the fourth output port of the plurality of second phase difference generators is connected to the antennas of the second- And may be respectively connected to the antennas of the second -2 polarized antenna group.

Wherein the first output ports of the plurality of first phase difference generators output a feed current of + 45 ° phase respectively and the second output ports of the plurality of first phase difference generators output feed currents of -45 ° phase respectively, And the third output port of the plurality of second phase difference generators outputs the feed current of -45 ° phase respectively and the fourth output port of the plurality of second phase difference generators outputs the feed current of -135 ° phase respectively .

A base station antenna apparatus according to another embodiment of the present invention includes: a 1-1 polarization antenna group including a plurality of antennas provided to have a first polarization; A 1-2 polarization antenna group including a plurality of antennas provided to have the first polarized wave and being spaced apart from the 1-1 polarized antenna group; A 2-1 polarization antenna group including a plurality of antennas arranged to have a second polarization; A second 2-polarized antenna group including a plurality of antennas provided to have the second polarized wave, the second 2-polarized antenna group being spaced apart from the 2-1 polarized antenna group; A first phase difference generator for generating a phase difference between a part of the first polarization antenna group and a part of the first polarization antenna group to form beams having different directivities; A second phase difference generator for generating a phase difference between the remainder of the first-first polarization antenna group and the rest of the first-second polarized wave antenna group so that the directivity of the beam is formed differently; A third phase difference generator for generating a phase difference between a part of the 2-1 polarization antenna group and a part of the 2-2 polarization antenna group so that the directivity of the beam is formed differently; And a fourth phase difference generator for generating a phase difference between the remainder of the second -1 polarization antenna group and the rest of the second 2 polarization antenna group so that the directivity of the beam is formed differently.

Wherein the first phase difference generator is arranged to generate a phase difference of 90 ° between a part of the first polarization antenna group and a part of the first polarization antenna group, And the third phase difference generator is arranged to generate a phase difference of 90 ° between the rest of the polarization antenna group and the rest of the first-second polarization antenna group, And the fourth phase difference generator is arranged such that a phase difference of 90 degrees is generated between the remainder of the second -1 polarization antenna group and the rest of the second 2 polarization antenna group .

Wherein the first phase difference generator and the second phase difference generator each have a first input port, a second input port, a first output port, and a second output port, A first power divider connected to a first output port of the first phase difference generator and supplying a feed current outputted from a first output port of the first phase difference generator to each antenna included in a part of the first 1-1 polarization antenna group; A second phase-difference generating unit connected to a second output port of the first phase-difference generating unit and supplying a power-supply current outputted from a second output port of the first phase-difference generating unit to each antenna included in a part of the first- Power divider; A third phase difference generator connected to the first output port of the second phase difference generator and supplying a feed current to be output from the first output port of the second phase difference generator to each antenna included in the remainder of the group of the first polarization antenna, Power divider; A fourth phase difference generator connected to a second output port of the second phase difference generator and supplying a feed current output from the second output port of the second phase difference generator to each antenna included in the remainder of the group of the first and second polarized wave antennas, Power divider; A fifth power divider connected to the first input port of the first phase difference generator and the first input port of the second phase difference generator, respectively, for supplying the feed current to the first phase difference generator and the second phase difference generator; And a sixth power divider connected to the second input port of the first phase difference generating section and the second input port of the second phase difference generating section and for supplying the feed current to the first phase difference generating section and the second phase difference generating section, As shown in FIG.

Wherein the third phase difference generator and the fourth phase difference generator each have a third input port, a fourth input port, a third output port, and a fourth output port, A seventh power divider connected to a third output port of the third phase difference generator and supplying a feed current outputted from a third output port of the third phase difference generator to each antenna included in a part of the second -1 polarization antenna group; And supplying the power supply current outputted from the fourth output port of the third phase difference generator to each antenna included in a part of the second 2-polarized wave antenna group, connected to the fourth output port of the third phase difference generator, Power divider; And a third feed port connected to a third output port of the fourth phase difference generator for feeding the feed current output from the third output port of the fourth phase difference generator to each antenna included in the remainder of the second- Power divider; And supplying the feed current to the respective antennas included in the remainder of the second -2 polarized antenna group, the feed current being connected to a fourth output port of the fourth phase difference generator and being output from the fourth output port of the fourth phase difference generator, Power divider; An eleventh power divider connected to the third input port of the third phase difference generator and the third input port of the fourth phase difference generator, respectively, for supplying the feed current to the third phase difference generator and the fourth phase difference generator; And a twelfth power divider connected to the fourth input port of the third phase difference generator and the fourth input port of the fourth phase difference generator and for supplying the feed current to the third phase difference generator and the fourth phase difference generator, As shown in FIG.

According to the embodiment of the present invention, the phase difference is generated in each of the two antenna groups having the first polarization and the two antenna groups having the second polarization, so that two beams having different directivities in the antenna group having the first polarization And two beams having different directivities are generated in the antenna group having the second polarized wave, so that multiple beams can be formed. In this case, the communication coverage of the base station can be enlarged, and the space occupied by the antenna at the base station does not need to be additionally secured.

1 is a view schematically showing a state in which antennas are arranged in a base station antenna apparatus according to an exemplary embodiment of the present invention;
2 is a view schematically showing a configuration of a base station antenna apparatus according to a first embodiment of the present invention;
3 is a view schematically showing the configuration of a base station antenna apparatus according to a second embodiment of the present invention.
4 is a view schematically showing a configuration of a base station antenna apparatus according to a third embodiment of the present invention;

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. The following detailed description is provided to provide a comprehensive understanding of the methods, apparatus, and / or systems described herein. However, this is merely an example and the present invention is not limited thereto.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification. The terms used in the detailed description are intended only to describe embodiments of the invention and should in no way be limiting. Unless specifically stated otherwise, the singular forms of the expressions include plural forms of meanings. In this description, the expressions "comprising" or "comprising" are intended to indicate certain features, numbers, steps, operations, elements, parts or combinations thereof, Should not be construed to preclude the presence or possibility of other features, numbers, steps, operations, elements, portions or combinations thereof.

In the following description, terms such as " transmission ", "transmission "," transmission ", "reception ", and similar terms of signal or information refer not only to the direct transmission of signals or information from one component to another But also through other components. In particular, "transmitting" or "transmitting" a signal or information to an element is indicative of the final destination of the signal or information and not a direct destination. This is the same for "reception" of a signal or information. Also, in this specification, the fact that two or more pieces of data or information are "related" means that when one piece of data (or information) is acquired, at least a part of the other data (or information) can be obtained based thereon.

On the other hand, directional terms such as the top, bottom, one side, the other, and the like are used in connection with the orientation of the disclosed figures. Since the elements of the embodiments of the present invention can be positioned in various orientations, directional terms are used for illustrative purposes and not limitation.

Also, the terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms may be used for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

FIG. 1 is a diagram schematically illustrating the arrangement of antennas in a base station antenna apparatus according to an exemplary embodiment of the present invention. Referring to FIG.

Referring to FIG. 1, the base station antenna apparatus 100 may include a first polarized antenna group 102 and a second polarized antenna group 104. The first polarized wave antenna group 102 is provided to have a first polarized wave and the second polarized wave antenna group 104 is provided to have a second polarized wave. For example, the first polarized wave may be polarized at +45 degrees and the second polarized wave may be polarized at -45 degrees. Alternatively, the first polarized wave may be 0 占 polarized, and the second polarized wave may be 90 占 polarized. Alternatively, the first polarization may be a left-handed polarization, and the second polarization may be a prior-art file. Alternatively, the first polarized wave may be a horizontal polarized wave, and the second polarized wave may be a vertical polarized wave file. Hereinafter, it is assumed that the first polarized wave is polarized at +45 degrees and the second polarized wave is polarized at -45 degrees.

Referring to FIG. 1 (a), the first polarized wave antenna group 102 may include a 1-1 polarized wave antenna group 102-1 and a 1-2 polarized wave antenna group 102-2. The second polarized wave antenna group 104 may include a second-first polarized wave antenna group 104-1 and a second-second polarized wave antenna group 104-2. The antennas belonging to the first-first polarization antenna group 102-1 may be arranged in the first direction in the base station antenna apparatus 100. [ The antennas belonging to the 1-2 polarized wave antenna group 102-2 may be arranged parallel to each other with the antennas belonging to the 1-1 polarization antenna group 102-1 in the base station antenna apparatus 100, respectively. The antennas belonging to the 2-1 polarized antenna group 104-1 may be arranged in a second direction perpendicular to the first direction in the base station antenna apparatus 100. [ The antennas belonging to the 2-2 polarized antenna group 104-2 can be arranged in parallel in opposition to the antennas belonging to the 2-1 polarized antenna group 104-1 in the base station antenna apparatus 100, respectively.

That is, the antenna belonging to the first-first polarized antenna group 102-1, the antenna belonging to the first polarized-wave antenna group 102-2, the antenna belonging to the second-first polarized antenna group 104-1, And the antennas belonging to the 2-2 polarized wave antenna group 104-2 constitute a unit antenna cell A, and each unit antenna cell A may be formed in a rhombus shape.

Referring to FIG. 1B, the antennas belonging to the 1-1 polarized antenna group 102-1 and the 1-2 polarized antenna group 102-2 are arranged in the first direction And can be arranged in a straight line. The antennas belonging to the 2-1 polarized antenna group 104-1 and the 2-2 polarized antenna group 104-2 are spaced apart from each other in the second direction perpendicular to the first direction in the base station antenna apparatus 100, Lt; / RTI > Here, the antennas belonging to the 1-1 polarization antenna group 102-1 and the 1-2 polarization antenna group 102-2 and the 2-1 polarization antenna group 104-1 and the 2-2 polarization The antennas belonging to the antenna group 104-2 may be arranged in a vertically crossing manner. That is, the unit antenna cell A may be formed in an X-shape.

2 is a diagram schematically showing a configuration of a base station antenna apparatus according to a first embodiment of the present invention.

Referring to FIG. 2, the base station antenna apparatus 100 includes a 1-1 polarization antenna group 102-1, a 1-2 polarization antenna group 102-2, a 2-1 polarization antenna group 104-1 A first phase difference generating unit 106, a first power dividing unit 108, a second power dividing unit 110, a second phase difference generating unit 112, A third power divider 114, and a fourth power divider 116. [ The first 1-1 polarized antenna group 102-1, the 1-2 polarized antenna group 102-2, the 2-1 polarized antenna group 104-1, and the 2-2 polarized antenna group 104- 2 have been described with reference to FIG. 1, a detailed description thereof will be omitted.

The first phase difference generator 106 serves to generate a phase difference between the 1-1 polarization antenna group 102-1 and the 1-2 polarization antenna group 102-2. The first phase difference generator 106 may cause a 90 ° phase difference to occur between the 1-1 polarization antenna group 102-1 and the 1-2 polarization antenna group 102-2. For example, the first phase difference generator 106 gives a + 45 ° phase to the 1-1 polarization antenna group 102-1 and the -45 ° phase to the 1-2 polarization antenna group 102-2 As shown in FIG.

The first phase difference generator 106 may include a first input port 106a, a second input port 106b, a first output port 106c, and a second output port 106d. The first output port 106c may be connected to the first power divider 108 and the second output port 106d may be connected to the second power divider 110. [ Feed currents may be supplied to the first input port 106a and the second input port 106b, respectively. The first phase difference generator 106 may output the feed current inputted to the first input port 106a to the first output port 106c after having the + 45 ° phase. The first phase difference generator 106 may output the feed current inputted to the second input port 106b to the second output port 106d after having the phase difference of -45 °. The first phase difference generator 106 generates a first phase difference between the power supply current input to the first input port 106a and the power supply current input to the second input port 106b in the first phase difference generator 106 So that a phase difference of 90 [deg.] Can be generated between each other.

The first power divider 108 may be provided by connecting the first phase difference generator 106 and the 1-1 polarization antenna group 102-1. The first power divider 108 can supply the feed currents output from the first phase difference generator 106 to the respective antennas of the 1-1 polarization antenna group 102-1. At this time, a feed current having a phase of + 45 ° can be supplied to each antenna of the 1-1 polarization antenna group 102-1.

The second power divider 110 may be provided by connecting the first phase difference generator 106 and the 1-2 polarized wave antenna group 102-2. The second power divider 110 can supply the feed current output from the first phase difference generator 106 to each antenna of the first and second polarized antenna group 102-2. At this time, a feeding current of -45 ° phase can be supplied to each antenna of the 1-2 polarized-wave antenna group 102-2.

The second phase difference generator 112 serves to generate a phase difference between the 2-1 polarized antenna group 104-1 and the 2-2 polarized antenna group 104-2. The second phase difference generator 112 may cause a 90 ° phase difference to occur between the 2-1 polarized antenna group 104-1 and the 2-2 polarized antenna group 104-2. For example, the second phase difference generator 112 gives a -45 ° phase to the 2-1 polarized antenna group 104-1 and the -135 ° phase to the 2-2 polarized antenna group 104-2 As shown in FIG.

The second phase difference generator 112 may include a third input port 112a, a fourth input port 112b, a third output port 112c, and a fourth output port 112d. Here, the third output port 112c may be connected to the third power divider 114, and the fourth output port 112d may be connected to the fourth power divider 116. And a feed current may be supplied to the third input port 112a and the fourth input port 112b, respectively. The second phase difference generator 112 may output the feed current inputted to the third input port 112a to the third output port 112c after having the phase difference of -45 °. The second phase difference generator 112 may output the feed current inputted to the fourth input port 112b to the fourth output port 112d after having the phase difference of -135 degrees.

The third power divider 114 may be provided to connect the second phase difference generator 112 and the second -1 polarization antenna group 104-1. The third power divider 114 can supply the feed current output from the second phase difference generator 112 to each antenna of the second -1 polarization antenna group 104-1. At this time, a feeding current having a phase of -45 [deg.] May be supplied to each antenna of the 2-1 polarized antenna group 104-1.

The fourth power divider 116 may be provided by connecting the second phase difference generator 112 and the second -2 polarization antenna group 104-2. The fourth power divider 116 can supply the feed current output from the second phase difference generator 112 to each antenna of the second -2 polarization antenna group 104-2. At this time, a feeding current having a phase of -135 占 can be supplied to each antenna of the second -2 polarized antenna group 104-2.

According to the embodiment of the present invention, two antenna groups (a 1-1 polarization antenna group and a 1-2 polarization antenna group) having a first polarization and two antenna groups (a 2-1 polarization Antenna group and the second-2 polarized wave antenna group), it is possible to generate two beams having different directivities in the antenna group having the first polarized wave, and to generate two beams having different directivities in the antenna group having the second polarized wave, A beam can be generated, and multiple beams can be formed. In this case, the communication coverage of the base station can be enlarged, and the space occupied by the antenna at the base station does not need to be additionally secured.

FIG. 3 is a view schematically showing a configuration of a base station antenna apparatus according to a second embodiment of the present invention.

3, the base station antenna apparatus 200 includes a 1-1 polarization antenna group 202-1, a 1-2 polarization antenna group 202-2, a 2-1 polarization antenna group 204-1 2-2 polarized wave antenna group 204-2, a plurality of first phase difference generators 206, a first power divider 208, a second power divider 210, a plurality of second phase difference generators 212, a third power divider 214, and a fourth power divider 216. The first 1-1 polarized antenna group 202-1, the 1-2 polarized antenna group 202-2, the 2-1 polarized antenna group 204-1, and the 2-2 polarized antenna group 204- 2 are the same as or similar to those described with reference to FIG. 1, so a detailed description thereof will be omitted.

The plurality of first phase difference generators 206 may cause a 90 ° phase difference to occur between the 1-1 polarization antenna group 202-1 and the 1-2 polarization antenna group 202-2. For example, a plurality of first phase difference generators 206 may provide a + 45 ° phase to the 1-1 polarization antenna group 202-1 and a 45th phase to the 1-2 polarization antenna group 202-2. Phase.

Each of the plurality of first phase difference generators 206 includes one antenna of the first 1-1 polarized antenna group 202-1, one antenna of the 1-2 polarized antenna group 202-2, The first power divider 208, and the second power divider 210. Specifically, each first phase difference generator 206 may include a first input port 206a, a second input port 206b, a first output port 206c, and a second output port 206d . Here, the first input port 206a may be connected to the first power divider 208, and the second input port 206b may be connected to the second power divider 210. The first output port 206c is connected to one of the 1-1 polarization antenna groups 202-1 and the second output port 206d is connected to the 1-2 polarization antenna group 202-2. Lt; RTI ID = 0.0 > antenna. ≪ / RTI >

Each of the first phase difference generating units 206 may output the feed current inputted to the first input port 206a to the first output port 206c after having a + 45 ° phase. The first phase difference generator 206 may output the feed current to the second output port 206d after having the feed current inputted to the second input port 206b to have a phase of -45 °.

The first power divider 208 can supply the input feed current to the plurality of first phase difference generators 206, respectively. The first power divider 208 may have a port (port 1) to which a feed current is input. The first power divider 208 can supply the input power supply current to the first input port 206a of each first phase difference generator 206. [

The second power divider 210 may supply the input feed current to the plurality of first phase difference generators 206, respectively. The second power divider 210 may include a port port 2 for receiving a feed current. The second power divider 210 can supply the input power supply current to the second input port 206b of each first phase difference generator 206. [

The plurality of second phase difference generators 212 may cause a 90 ° phase difference to occur between the 2-1 polarized antenna group 204-1 and the 2-2 polarized antenna group 204-2. For example, the plurality of second phase difference generators 212 may provide -45 ° phase to the 2-1 polarized antenna group 204-1 and the -45 ° phase to the 2-2 polarized antenna group 204-2. Phase.

Each of the plurality of second phase difference generators 212 includes one antenna of the 2-1 polarized antenna group 204-1, one antenna of the 2-2 polarized antenna group 204-2, The first power divider 214, and the fourth power divider 216. Specifically, each second phase difference generator 212 may include a third input port 212a, a fourth input port 212b, a third output port 212c, and a fourth output port 212d . The third input port 212a may be connected to the third power divider 214 and the fourth input port 212b may be connected to the fourth power divider 216. [ The third output port 212c is connected to one of the second-1 polarized antenna group 204-1 and the fourth output port 212d is connected to the second-2 polarized antenna group 204-2. Lt; RTI ID = 0.0 > antenna. ≪ / RTI >

The second phase difference generator 212 may output the current to the third output port 212c after having the feed current inputted to the third input port 212a to have a phase of -45 °. The second phase difference generator 212 may output the feed current to the fourth input port 212b after having the feed current inputted to the fourth input port 212b to have a phase of -135 °.

The third power divider 214 may supply the input power supply current to the plurality of second phase difference generators 212, respectively. The third power divider 214 may have a port (port 3) to which a feed current is input. The third power divider 214 can supply the input power supply current to the third input port 212a of each second phase difference generator 212. [

The fourth power divider 216 may supply the input feed current to the plurality of second phase difference generators 212, respectively. The fourth power divider 216 may include a port port 4 for receiving a feed current. The fourth power divider 216 can supply the input power supply current to the fourth input port 212b of each second phase difference generator 212. [

4 is a diagram schematically showing a configuration of a base station antenna apparatus according to a third embodiment of the present invention.

Referring to FIG. 4, the base station antenna apparatus 300 includes a 1-1 polarization antenna group 302-1, a 1-2 polarization antenna group 302-2, a 2-1 polarization antenna group 304-1 A first phase difference generator 306, a first power divider 308, a second power divider 310, a second phase difference generator 312, a second phase difference generator 312, 3 power divider 314, a fourth power divider 316, a fifth power divider 318, a sixth power divider 320, a third phase difference generator 322, a seventh power divider 324, A fourth phase difference generator 328, a ninth power divider 330, a tenth power divider 332, an eleventh power divider 334 and a twelfth power divider 336 .

The 1-1 polarization antenna group 302-1 may be divided into a 1-1a polarization antenna group 302a-1 and a 1-1b polarization antenna group 302b-1. That is, when the number of antennas included in the first-first polarized wave antenna group 302-1 is large, the first-first polarized wave antenna group 302-1 is divided into two groups, that is, 1 polarized wave antenna group 302a-1 and the 1-1b polarized wave antenna group 302b-1. The arrangement directions of the 1-1a polarized antenna group 302a-1 and the 1-1b polarized antenna group 302b-1 may be the same.

Likewise, the 1-2 polarized-wave antenna group 302-2 can be divided into the 1-2a polarized antenna group 302a-2 and the 1-2b polarized antenna group 302b-2. The 2-1 polarized antenna group 304-1 can be divided into a 2-1a polarized antenna group 304a-1 and a 2-1b polarized antenna group 304b-1. The 2-2 polarized antenna group 304-1 may be divided into a 2-2a polarized antenna group 304a-2 and a 2-2b polarized antenna group 304b-2.

The first phase difference generator 306 may cause a 90 ° phase difference to occur between the 1-1a polarized wave antenna group 302a-1 and the 1-2a polarized wave antenna group 302a-2. For example, the first phase difference generator 306 gives + 45 ° phase to the 1-1a polarized wave antenna group 302a-1 and 45 ° phase to the 1-2a polarized wave antenna group 302a-2 As shown in FIG.

The first phase difference generator 306 may include a first input port 306a, a second input port 306b, a first output port 306c, and a second output port 306d. The first output port 306c may be connected to the first power divider 308 and the second output port 306d may be connected to the second power divider 310. [ The first input port 306a may be coupled to the fifth power divider 318 and the second input port 306b may be coupled to the sixth power divider 320. [ The first phase difference generator 306 may output the feed current inputted to the first input port 306a to the first output port 306c after having the + 45 ° phase. The first phase difference generator 306 may output the feed current inputted to the second input port 306b to the second output port 306d after having a phase of -45 °.

The first power divider 308 may be provided by connecting the first phase difference generator 306 and the 1-1a polarized wave antenna group 302a-1. The first power divider 308 can supply the feed currents output from the first phase difference generator 306 to the respective antennas of the 1-1a polarized antenna group 302a-1. At this time, a feeding current having a + 45 ° phase may be supplied to each antenna of the 1-1a polarized wave antenna group 302a-1.

The second power divider 310 may be provided by connecting the first phase difference generator 306 and the 1-2a polarized wave antenna group 302a-2. The second power divider 310 can supply the feed current output from the first phase difference generator 306 to each antenna of the 1-2a polarized wave antenna group 302a-2. At this time, a feeding current of -45 ° phase can be supplied to each antenna of the 1-2a polarized wave antenna group 302a-2.

The second phase difference generator 312 may cause a 90 ° phase difference to occur between the 1-1 b polarized wave antenna group 302b-1 and the 1-2b polarized wave antenna group 302b-2. For example, the second phase difference generator 312 gives + 45 ° phase to the 1-1b polarized wave antenna group 302b-1 and the -45 ° phase to the 1-2b polarized wave antenna group 302b- As shown in FIG.

The second phase difference generator 312 may include a first input port 312a, a second input port 312b, a first output port 312c, and a second output port 312d. Here, the first output port 312c may be connected to the third power divider 314, and the second output port 312d may be connected to the fourth power divider 316. The first input port 312a may be connected to the fifth power divider 318 and the second input port 312b may be connected to the sixth power divider 320. [ The second phase difference generator 312 may output the feed current inputted to the first input port 312a to the first output port 312c after having the + 45 ° phase. The second phase difference generator 312 may output the power supply current input to the second input port 312b to the second output port 312d after having a phase of -45 °.

The third power divider 314 may be provided by connecting the second phase difference generator 312 and the 1-1b polarized wave antenna group 302b-1. The third power divider 314 can supply the feed currents output from the second phase difference generator 312 to the respective antennas of the 1-1b polarized wave antenna group 302b-1. At this time, a feed current having a phase of + 45 ° can be supplied to each antenna of the 1-1b polarized wave antenna group 302b-1.

The fourth power divider 316 may be provided by connecting the second phase difference generator 312 and the 1-2b polarized wave antenna group 302b-2. The fourth power divider 316 can supply the feed current output from the second phase difference generator 312 to each antenna of the first and second polarized wave antenna groups 302b-2. At this time, a feeding current having a phase of -45 ° can be supplied to each antenna of the 1-2b polarized wave antenna group 302b-2.

The fifth power divider 318 can supply the input feed current to the first phase difference generator 306 and the second phase difference generator 312, respectively. The fifth power divider 318 may have a port (port 1) through which a feeding current is inputted. The fifth power divider 318 can supply the input power supply current to the first input port 306a of the first phase difference generator 306 and the first input port 312a of the second phase difference generator 312 have.

The sixth power divider 320 can supply the input feed current to the first phase difference generator 306 and the second phase difference generator 312, respectively. The sixth power divider 320 may have a port (port 2) through which a power supply current is input. The sixth power divider 320 can supply the input feed current to the second input port 306b of the first phase difference generator 306 and the second input port 312b of the second phase difference generator 312 have.

The third phase difference generator 322 may cause a 90 ° phase difference to occur between the 2-1a polarized wave antenna group 304a-1 and the 2-2a polarized wave antenna group 304a-2. For example, the third phase difference generator 322 gives a -45 ° phase to the 2-1a polarized wave antenna group 304a-1 and the -135 ° phase to the 2-2a polarized wave antenna group 304a-2 As shown in FIG.

The third phase difference generator 322 may include a third input port 322a, a fourth input port 322b, a third output port 322c, and a fourth output port 322d. The third output port 322c may be connected to the seventh power divider 324 and the fourth output port 322d may be connected to the eighth power divider 326. [ The third input port 322a may be connected to the eleventh power divider 334 and the fourth input port 322b may be connected to the twelfth power divider 336. [ The third phase difference generator 322 may output the feed current inputted to the third input port 322a to the third output port 22c after having a phase of -45 °. The third phase difference generating unit 322 may output the feed current inputted to the fourth input port 322b to the fourth output port 322d after having a phase of -135 °.

The seventh power divider 324 may be provided to connect the third phase difference generator 322 and the second -1a polarized wave antenna group 304a-1. The seventh power divider 324 can supply the feed current output from the third phase difference generator 322 to each antenna of the second -1 la polarized antenna group 304a-1. At this time, a feed current having a phase of -45 [deg.] May be supplied to each antenna of the 2-1a polarized wave antenna group 304a-1.

The eighth power divider 326 may be provided to connect the third phase difference generator 322 and the second -2a polarized wave antenna group 304a-2. The eighth power divider 326 can supply the feed current output from the third phase difference generator 322 to each antenna of the second -2a polarized wave antenna group 304a-2. At this time, a feed current having a phase of -135 占 can be supplied to each antenna of the second -2a polarized wave antenna group 304a-2.

The fourth phase difference generator 328 may cause a 90 ° phase difference to occur between the 2-1b polarized wave antenna group 304b-1 and the 2-2b polarized wave antenna group 304b-2. For example, the fourth phase difference generator 328 may provide a -45 ° phase to the 2-1b polarized wave antenna group 304b-1 and a-135 ° phase to the 2-2b polarized wave antenna group 304b- As shown in FIG.

The fourth phase difference generator 328 may include a third input port 328a, a fourth input port 328b, a third output port 328c, and a fourth output port 328d. The third output port 328c may be connected to the ninth power divider 330 and the fourth output port 328d may be connected to the tenth power divider 332. [ The third input port 328a may be coupled to the eleventh power divider 332 and the fourth input port 328b may be coupled to the twelfth power divider 336. [ The fourth phase difference generating unit 328 may output the feed current inputted to the third input port 328a to the third output port 328c after having the -45 ° phase. The fourth phase difference generator 328 may output the feed current inputted to the fourth input port 328b to the fourth output port 328d after having a phase of -135 degrees.

The ninth power divider 330 may be provided to connect the fourth phase difference generator 328 and the second -1b polarized wave antenna group 304b-1. The ninth power divider 330 can supply the feed current output from the fourth phase difference generator 328 to each antenna of the second -1b polarized wave antenna group 304b-1. At this time, a feeding current having a phase of -45 占 may be supplied to each antenna of the second-1b polarized wave antenna group 304b-1.

The tenth power divider 332 may be provided by connecting the fourth phase difference generator 328 and the second -2b polarized wave antenna group 304b-2. The tenth power divider 332 can supply the feed current output from the fourth phase difference generator 328 to each antenna of the second -2b polarized wave antenna group 304b-2. At this time, a feed current having a phase of -135 占 can be supplied to each antenna of the second -2b polarized wave antenna group 304b-2.

The eleventh power divider 334 may supply the input feed current to the third phase difference generator 322 and the second phase difference generator 328, respectively. The eleventh power divider 334 may have a port (port 3) through which a feeding current is inputted. The eleventh power divider 334 can supply the input power supply current to the third input port 322a of the third phase difference generator 322 and the third input port 328a of the fourth phase difference generator 328 have.

The twelfth power divider 336 can supply the input feed current to the third phase difference generator 322 and the fourth phase difference generator 328, respectively. The twelfth power divider 336 may have a port (port 4) through which a feeding current is inputted. The twelfth power divider 336 can supply the input feed current to the fourth input port 322b of the third phase difference generator 322 and the fourth input port 328b of the fourth phase difference generator 328 have.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, . Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by equivalents to the appended claims, as well as the appended claims.

100, 200, 300: base station antenna device
102: first polarized antenna group
104: second polarized wave antenna group
102-1, 202-1, and 302-1: group 1-1 polarization antenna group
102-2, 202-2, and 302-2: the first and second polarized antenna groups
104-1, 204-1, and 304-1: the 2-1 polarized antenna group
104-2, 204-2, 304-2: 2-2 polarized antenna group
106, 206, and 306: the first phase difference generator
106a, 206a, 306a: a first input port
106b, 206b, 306b: a second input port
106c, 206c, and 306c:
106d, 206d, 306d: a second output port
108, 208, 308: a first power divider
110, 210, 310: a second power divider
112, 212, 312: the second phase difference generator
112a, 212a: a third input port
112b, 212b: a fourth input port
112c and 212c: a third output port
112d and 212d: a fourth output port
114, 214, 314: a third power divider
116, 216, 316: fourth power divider
318: Fifth power divider
320: Sixth power divider
322: Third phase difference generator
324: Seventh power divider
326: Eighth power divider
328: Fourth phase difference generator
322a, 328a: a third input port
322b, 328b: a fourth input port
322c, 328c: a third output port
322d, 328d: fourth output port
330: 9th power divider
332: 10th power divider
334: 11th power divider
336: twelfth power divider

Claims (12)

A 1-1 polarization antenna group including a plurality of antennas arranged to have a first polarization;
A 1-2 polarization antenna group including a plurality of antennas provided to have the first polarized wave and being spaced apart from the 1-1 polarized antenna group;
A 2-1 polarization antenna group including a plurality of antennas arranged to have a second polarization;
A second 2-polarized antenna group including a plurality of antennas provided to have the second polarized wave, the second 2-polarized antenna group being spaced apart from the 2-1 polarized antenna group;
A first phase difference generator for generating a phase difference between the first 1-1 polarization antenna group and the 1-2 polarization antenna group so that beam directivity is differently formed; And
And a second phase difference generator for generating a phase difference between the 2-1 polarized antenna group and the 2-2 polarized antenna group so that beam directivity is differently formed.
The method according to claim 1,
Wherein the first phase difference generator is configured to generate a phase difference of 90 ° between the first 1-1 polarization antenna group and the 1-2 polarization antenna group,
Wherein the second phase difference generator is provided such that a phase difference of 90 ° occurs between the second-1 polarized antenna group and the second -2 polarized antenna group.
The method of claim 2,
Wherein the first phase difference generator includes a first input port and a second input port to which a feed current is input and a first output port and a second output port through which a feed current having a phase difference of 90 ° with respect to each other is output,
Wherein the second phase difference generator includes a third input port and a fourth input port to which a feed current is input and a third output port and a fourth output port through which a feed current having a phase difference of 90 ° with respect to each other is output,
The base station antenna apparatus includes:
A first power divider connected to a first output port of the first phase difference generator and supplying a feed current output from the first output port to each antenna of the first 1-1 polarization antenna group;
A second power divider connected to a second output port of the first phase difference generator and supplying a feed current output from the second output port to each antenna of the first and second polarization antenna groups;
A third power divider connected to a third output port of the second phase difference generator and supplying a feed current output from the third output port to each antenna of the second -1 polarization antenna group; And
Further comprising a fourth power divider connected to a fourth output port of the second phase difference generator and supplying a feed current output from the fourth output port to each antenna of the second -2 polarization antenna group, Device.
The method of claim 3,
Wherein the first output port of the first phase difference generator outputs a feed current in the + 45 ° phase and the second output port of the first phase difference generator outputs a feed current in the -45 ° phase,
Wherein the third output port of the second phase difference generator outputs a feed current of -45 ° phase and the fourth output port of the second phase difference generator is arranged to output a feed current of -135 ° phase.
The method of claim 2,
The first phase difference generator is provided with a plurality of antennas corresponding to the antennas included in the first 1-1 polarization antenna group and the 1-2 polarization antenna group,
The second phase difference generator is provided with a plurality of antennas corresponding to the antennas included in the 2-1 polarized antenna group and the 2-2 polarized antenna group,
Wherein each of the plurality of first phase difference generators has a first input port, a second input port, a first output port, and a second output port,
The plurality of second phase difference generators each include a third input port, a fourth input port, a third output port, and a fourth output port,
The base station antenna apparatus includes:
A first power divider for supplying the input power supply current to the first input port of the plurality of first phase difference generators;
A second power divider for supplying the input power supply current to a second input port of the plurality of first phase difference generators;
A third power divider that supplies the input power supply current to a third input port of the plurality of second phase difference generators; And
And a fourth power divider for respectively supplying the input power supply current to a fourth input port of the plurality of second phase difference generators.
The method of claim 5,
The first output port of the plurality of first phase difference generators is connected to the antennas of the group of the first polarization antenna group,
A second output port of the plurality of first phase difference generators is connected to the antennas of the first and second polarized wave antenna groups,
The third output port of the plurality of second phase difference generators is connected to the antennas of the second-1 polarization antenna group,
And the fourth output port of the plurality of second phase difference generators is connected to the antennas of the second -2 polarization antenna group, respectively.
The method of claim 6,
Wherein the first output ports of the plurality of first phase difference generators output a feed current of + 45 ° phase respectively and the second output ports of the plurality of first phase difference generators output feed currents of -45 ° phase respectively,
And the third output port of the plurality of second phase difference generators outputs the feed current of -45 ° phase respectively and the fourth output port of the plurality of second phase difference generators outputs the feed current of -135 ° phase respectively The base station antenna device.
A 1-1 polarization antenna group including a plurality of antennas arranged to have a first polarization;
A 1-2 polarization antenna group including a plurality of antennas provided to have the first polarized wave and being spaced apart from the 1-1 polarized antenna group;
A 2-1 polarization antenna group including a plurality of antennas arranged to have a second polarization;
A second 2-polarized antenna group including a plurality of antennas provided to have the second polarized wave, the second 2-polarized antenna group being spaced apart from the 2-1 polarized antenna group;
A first phase difference generator for generating a phase difference between a part of the first polarization antenna group and a part of the first polarization antenna group to form beams having different directivities;
A second phase difference generator for generating a phase difference between the remainder of the first-first polarization antenna group and the rest of the first-second polarized wave antenna group so that the directivity of the beam is formed differently;
A third phase difference generator for generating a phase difference between a part of the 2-1 polarization antenna group and a part of the 2-2 polarization antenna group so that the directivity of the beam is formed differently; And
And a fourth phase difference generator for generating a phase difference between the remainder of the 2-1 polarized antenna group and the remainder of the 2-2 polarized antenna group so that the directivity of the beam is formed differently.
The method of claim 8,
Wherein the first phase difference generator is arranged to generate a phase difference of 90 DEG between a part of the first 1-1 polarization antenna group and a part of the first 1-2 polarization antenna group,
The second phase difference generator is arranged to generate a phase difference of 90 ° between the remainder of the group of the first polarization antenna groups and the rest of the first and second polarization antenna groups,
Wherein the third phase difference generator is arranged to generate a phase difference of 90 DEG between a part of the second -1 polarization antenna group and a part of the second 2 polarization antenna group,
Wherein the fourth phase difference generator is arranged such that a phase difference of 90 DEG occurs between the remainder of the second-first polarized antenna group and the rest of the second-second polarized antenna group.
The method of claim 9,
Wherein the first phase difference generator and the second phase difference generator each have a first input port, a second input port, a first output port, and a second output port,
The base station antenna apparatus includes:
A first phase difference generator connected to a first output port of the first phase difference generator and supplying a feed current outputted from a first output port of the first phase difference generator to each antenna included in a part of the first 1-1 polarization antenna group, Power divider;
A second phase-difference generating unit connected to a second output port of the first phase-difference generating unit and supplying a power-supply current outputted from a second output port of the first phase-difference generating unit to each antenna included in a part of the first- Power divider;
A third phase difference generator connected to the first output port of the second phase difference generator and supplying a feed current to be output from the first output port of the second phase difference generator to each antenna included in the remainder of the group of the first polarization antenna, Power divider;
A fourth phase difference generator connected to a second output port of the second phase difference generator and supplying a feed current output from the second output port of the second phase difference generator to each antenna included in the remainder of the group of the first and second polarized wave antennas, Power divider;
A fifth power divider connected to the first input port of the first phase difference generator and the first input port of the second phase difference generator, respectively, for supplying the feed current to the first phase difference generator and the second phase difference generator; And
A sixth power divider connected to the second input port of the first phase difference generator and the second input port of the second phase difference generator and supplying a feed current to the first phase difference generator and the second phase difference generator, And the base station antenna device further comprises:
The method of claim 10,
Wherein the third phase difference generator and the fourth phase difference generator each have a third input port, a fourth input port, a third output port, and a fourth output port,
The base station antenna apparatus includes:
And a seventh unit that is connected to the third output port of the third phase difference generating unit and supplies the feed current outputted from the third output port of the third phase difference generating unit to each antenna included in a part of the second- Power divider;
And supplying the power supply current outputted from the fourth output port of the third phase difference generator to each antenna included in a part of the second 2-polarized wave antenna group, connected to the fourth output port of the third phase difference generator, Power divider;
And a third feed port connected to a third output port of the fourth phase difference generator for feeding the feed current output from the third output port of the fourth phase difference generator to each antenna included in the remainder of the second- Power divider;
And supplying the feed current to the respective antennas included in the remainder of the second -2 polarized antenna group, the feed current being connected to a fourth output port of the fourth phase difference generator and being output from the fourth output port of the fourth phase difference generator, Power divider;
An eleventh power divider connected to the third input port of the third phase difference generator and the third input port of the fourth phase difference generator, respectively, for supplying the feed current to the third phase difference generator and the fourth phase difference generator; And
A twelfth power divider connected to the fourth input port of the third phase difference generator and the fourth input port of the fourth phase difference generator and for supplying the feed current to the third phase difference generator and the fourth phase difference generator, And the base station antenna device further comprises:
A base station including the base station antenna apparatus according to any one of claims 1 to 11.

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