The present invention relates to an antenna that is applicable to a base station or a relay station in a mobile communication (PCS, cellular, CDMA, GSM, LTE, or the like) network, and in particular, to an omnidirectional antenna.
An omnidirectional antenna, called a non-directional antenna, is an antenna designed to radiate electromagnetic waves uniformly all around 360 degrees in the horizontal direction. In a mobile communication network, it is impossible to predict a direction where a mobile communication terminal moves due to a characteristic thereof. Thus, the mobile communication terminal is typically provided with an omnidirectional antenna that employs a circular monopole antenna structure. An antenna installed in a mobile communication network base station or relay station is usually provided with a directional antenna for directing each service range divided into three sectors.
Recently, as the Long Term Evolution (LTE) service has become more popular, it is required to construct a small cell or an ultra-small cell equipment for ensuring a smooth service in a shaded area, such as the inside of a building, and also for increasing a data transmission speed. Small cells for outdoor use are serviced at a coverage of 0.5 to 1.5 km, and a small size is also required for the equipment itself. Thus, as an antenna applied to the corresponding equipment, it may be useful to adopt an omnidirectional antenna.
A commonly used omnidirectional antenna mainly uses single polarization (V-pol). However, a MIMO (Multi Input Multi Output) technology is inevitable for the LTE service, and a dual polarization antenna is indispensable for this purpose. In an omnidirectional antenna, a conventional dual polarization means an H-polarization (H-pol; 0 degrees) and a vertical polarization (V-pol; 90 degrees).
However, a +/−45 degree dual polarization has the lowest correlation between the two polarizations in terms of the reflection or diffraction of radio waves due to fading. Thus, a directional antenna, which is usually applied to the base station or the relay station, mainly uses the +/−45 degree dual polarization. Accordingly, studies have been made to generate the +/−45 degree dual polarization even in an omnidirectional antenna. However, it is difficult to implement a structure for generating the +/−45 degree dual polarization while satisfying omni-directionally even radiation characteristics. Furthermore, it is more difficult to implement an omnidirectional antenna in a small size in consideration of the fact that it is installed in a small cell, such as inside a building, while generating the +/−45 degree dual polarization.
Accordingly, an object of the present invention is to provide an omnidirectional antenna for a mobile communication service, which is capable of generating a +45 degree or −45 degree polarization while satisfying excellent omnidirectional radiation characteristics.
Another object of the present invention is to provide an omnidirectional antenna for a mobile communication service, which is capable of generating a +/−45 degree dual polarization.
Still another object of the present invention is to provide an omnidirectional antenna for a mobile communication service, which is capable of generating a +/−45 degree dual polarization while implementing the omnidirectional antenna in a small size.
In order to achieve the above-described objects, according to an aspect of the present invention, there is provided an omnidirectional antenna for a mobile communication service, which includes: a plurality of radiation elements arranged on a horizontal plane with a mutually identical angle so as to radiate beams, respectively; and a power supply unit that distributes and provides feeding signals to each of the plurality of radiation elements. Each of the plurality of radiation elements has a structure in which a horizontal polarization dipole radiation unit having two radiation arms and a vertical polarization dipole radiation unit having two radiation arms are coupled to each other.
Each of the plurality of radiation elements may be formed through a pattern printing manner using a Flexible Printed Circuit Board (FPCB).
The plurality of radiation elements may be successively arranged on the FPCB at a predetermined interval, and the FPCB may be provided in a cylindrical shape.
Each of the plurality of radiation elements may have a structure in which one radiation arm and the other radiation arm of the horizontal polarization dipole radiation unit are connected to one radiation arm and the other radiation arm of the vertical polarization dipole radiation unit, respectively, at the center of the corresponding radiation element, or the one radiation arm and the other radiation arm of the horizontal polarization dipole radiation unit are connected to the other radiation arm and the one radiation arm of the vertical polarization dipole radiation unit, respectively, at the center of the corresponding radiation element. A design may be made such that power is simultaneously supplied to the portions where the horizontal polarization dipole radiation pattern and the vertical polarization dipole radiation pattern are connected.
According to another aspect of the present invention, there is provided an omnidirectional antenna for a mobile communication service, which includes: a plurality of radiation element arrays each including a plurality of radiation elements arranged on a horizontal plane with a mutually identical angle so as to radiate beams, respectively, the radiation element arrays being successively arranged in a vertical direction; and a feeding unit that distributes and provides feeding signals to each of the plurality of radiation element arrays. Each of the plurality of radiation elements of each of the plurality of radiation element arrays may have a structure in which a horizontal dipole radiation unit having two radiation arms and a vertical polarization dipole radiating part having two radiation arms are coupled to each other.
Each of the plurality of radiation element arrays is configured with first type radiation elements in which each of the plurality of radiation elements has a structure in which one radiation arm and the other radiation arm of the horizontal polarization dipole radiation unit are connected to one radiation arm and the other radiation arm of the vertical polarization dipole radiation unit, respectively, at the center of the corresponding radiation element, or configured with second type radiation elements in which the one radiation arm and the other radiation arm of the horizontal polarization dipole radiation unit are connected to the other radiation arm and the one radiation arm of the vertical polarization dipole radiation unit, respectively, at the center of the corresponding radiation element. A design may be made such that power is simultaneously supplied to the portions where the horizontal polarization dipole radiation pattern and the vertical polarization dipole radiation pattern are connected.
In each of the plurality of radiation element arrays, the plurality of radiation elements may be simultaneously formed through a pattern printing manner using one FPCB.
In each of the plurality of radiation element arrays, the plurality of radiation elements are constituted by first to third radiation elements, and the FPCB on which the first to third radiation elements are formed may be provided in a cylindrical structure.
The plurality of radiation element arrays may have a combination structure of at least one radiation element array configured with the first type radiation elements and at least one radiation element array configured with the second type radiation elements.
The plurality of radiation element arrays have a structure in which the first to fourth radiation element arrays are successively arranged in the vertical direction, the first and second radiation element arrays are configured with the first type or second type radiation elements, and the third and fourth radiation element arrays are configured with radiation elements of which the type are different from that of the first and second radiation element arrays.
The feeding unit that distributes and provides feeding signals to each of the plurality of radiation element arrays may include a plurality of feeding boards having a feeding pattern that provides a feeding signal to each of the plurality of radiation element arrays, and each of the plurality of feeding boards includes an inner layer; a feeding pattern formed on a top surface of the inner layer and having a plurality of coupling feeding patterns that respectively supply power to the plurality of radiation elements formed on a corresponding radiation element array in a coupling manner; and a ground pattern formed on a bottom surface of the inner layer.
Each of the plurality of feeding boards may be fed with power through a plurality of feeding lines, respectively, at least one connection passage through which at least one of the feeding lines, which feed power to different feeding boards, passes may be formed in a form of a through hole, and the feeding line passing through the connection path may be soldered to the ground pattern.
The above and other aspects, features, and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which:
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, specific features, such as specific components, are illustrated merely for helping the general understanding of the present invention. It will be obvious to a person ordinarily skilled in the art that certain modifications or changes may be made to the specific features without departing from the scope of the present invention.
Referring to
That is, the one radiation arm 110d of the horizontal polarization dipole radiation unit and the one radiation arm 110a of the vertical polarization dipole radiation unit are integrally provided as a pair, and the other radiation arm 110b of the horizontal polarization dipole radiation unit and the other radiation arm 110c of the vertical polarization dipole radiation unit are integrally provided as a pair.
Referring to the configuration of a feeding unit that provides a feeding signal to each radiation element 11, the feeding point P of each radiation element 11 is connected to a feeding line 14 (see, e.g.,
The radiation patterns of each of the first to third radiation elements 11 may be made by forming a thin metal plate (e.g., a copper plate). In addition, as illustrated in the example of
Here, descriptions will be made, by way of an example, with reference to a technology in which the plurality of radiation elements 11 are implemented on the FPCB. The plurality of radiation elements may be formed using a copper plate bent in a circular or oval shape without being limited to the PCB. Instead of the FPCB, a conventional flat PCB may be formed in a polygonal shape, such as a triangular shape or a quadrangular shape, to dispose a plurality of radiation elements thereon. One or more radiation elements may be disposed on each flat PCB.
As illustrated in
At this time, in each of the radiation elements, the one radiation arm 113d of the horizontal polarization dipole radiation unit and the other radiation arm 113c of the vertical polarization dipole radiation unit are connected to a feeding point P positioned at the center of the radiation element 113, and the other radiation arm 113b of the horizontal polarization dipole radiation unit and the other radiation arm 113c of the vertical polarization dipole radiation unit are connected to each other at a portion corresponding to the feeding point P. That is, the one radiation arm 113d of the horizontal polarization dipole radiation unit and the other radiation arm 113c of the vertical polarization dipole radiation unit are integrally provided as a pair, and the other radiation arm 113b of the horizontal polarization dipole radiation unit and the other radiation arm 113c of the vertical polarization dipole radiation unit are integrally provided as a pair.
At this time, the feeding unit is designed such that a connection part where the one radiation arm 113d of the horizontal polarization dipole radiation unit and the other radiation arm 113c of the vertical polarization dipole radiation unit are connected to each other and a connection part where the other radiation arm 113b of the horizontal polarization dipole radiation unit and the one radiation arm 113a of the vertical polarization dipole radiation unit are connected to each other are simultaneously fed with power through the feeding point P.
It can be seen that this structure is a structure that generates polarization in the −45 degree direction. Desired +45 degree or −45 degree polarization can be selectively generated by forming the radiation patterns of the first to fourth radiation elements of the structure illustrated in
The omnidirectional antenna according to the embodiment of the present invention is formed by combining the first to third radiation elements 11, which have the same configuration as shown in
As illustrated in
Meanwhile, in the above-described configuration of the omnidirectional antenna according to the first embodiment of the present invention, when the first to third radiation elements 11 are constituted with the first type structure illustrated in
That is, the omnidirectional antenna according to the second embodiment of the present invention may be configured by continuously arranging first to fourth radiation element arrays 21, 22, 23, and 24 in the vertical direction. At this time, the first and second radiation element arrays 21 and 22 may be constituted with the second type radiation elements illustrated in
Accordingly, as illustrated in
As the spacing distance S between the radiation element arrays generating different polarizations (e.g., the second and third radiation element arrays) is increased, the isolation characteristic is improved. However, it is necessary to reduce the separation distance S for the miniaturization of the antenna and the like. There are several factors that influence the spacing distance S. As the radiation beam width of each of the radiation element arrays decreases, the interference between the radiation element arrays may be reduced and the spacing distance S may be further reduced. Also, the spacing distance S is inversely proportional to the number of radiation element arrays.
In addition, a spacing distance g between the radiation element arrays generating the same polarization (e.g., the first and second radiation element arrays, or the third and fourth radiation element arrays) may be properly set in consideration of a sidelobe characteristic, a gain, and the like. For example, the spacing distance g may be set to about 0.75 to 0.8λ (λ: wavelength) with respect to a processing frequency. Since the spacing distance g is proportional to the magnitudes of the gain and the sidelobe, the smaller the spacing distance g is, the smaller the sidelobe can be. This makes it possible to further miniaturize the omnidirectional antenna.
Further, in order to secure a higher isolation between the radiation element arrays having the same polarization, the radiation element arrays are installed to relatively have a difference of about 60 degrees on a horizontal plane. For example, as more clearly illustrated in
The omnidirectional antenna according to the second embodiment of the present invention may be constructed as illustrated in
As described above, the flexible printed circuit board 232 or 212, on which the three radiation elements 23-1, 23-2, and 23-3, or 21-1, 21-2, and 21-3 are successively formed, is installed in a form in which the flexible printed circuit board 232 or 212 is subsequently rolled in a cylindrical shape, and both sides to be in contact with each other are bonded and fixed to each other. As described later, the radiation elements installed on the flexible printed circuit board 232 or 212 may have a structure in which power is fed through a feeding board 33 (e.g., see
At this time, in each flexible printed circuit board 232 or 212, for each radiation element 23-1, 23-2, and 23-3, or 21-1, 21-2, and 21-3, each of two radiation arms of the horizontal polarization radiation unit may have a through hole 235 or 215 formed in the vicinity of the feeding point. In addition, the feeding board 33 (see, e.g.,
In
As can be clearly understood from the configuration illustrated in
The feeding patterns 332 (332-1, 332-2, and 332-3) include first to third coupling feeding patterns 332-2, 332-1, and 332-3 configured to feed power to three radiation elements formed on a corresponding radiation element array 23. The first to third coupling feeding patterns 332-2, 332-1, and 332-3 include a pattern for feeding power, in a coupling manner, to the respective radiation elements of the corresponding radiation element array 23 in the protrusion a where the feeding board 33 and the radiation element array 23 are coupled to each other. Each of the first to third coupling feeding patterns 332-2, 332-1, and 332-3 is patterned in a structure to receive feeding signals distributed from one feeding point P formed at the center of the feeding substrate 33. The feeding point P is configured to receive a feeding signal through a feeding line (e.g., the feeding line 43) that may be configured with a coaxial cable.
A connection structure of the feeding board 33 and the feeding line 43 is illustrated in more detail in a circular region A indicated by a one-dot chain line in
The feeding patterns 312 (312-1, 312-2, and 312-3) include first to third coupling feeding patterns 312-2, 312-1, and 312-3 configured to feed power to three radiation elements formed on a corresponding radiation element array 21. Each of the first to third coupling feeding patterns 312-2, 312-1, and 312-3 is patterned in a structure to receive feeding signals distributed from one feeding point P formed at the center of the feeding substrate 31. The feeding point P is configured to receive a feeding signal through a feeding line that may be configured with a coaxial cable.
At this time, the first to third coupling feeding patterns 312-1, 312-2, and 312-3 formed on the second type feeding board 31 are somewhat different from those formed on the feeding board 33 illustrated in
In this configuration, the feeding lines (the feeding lines 41, 43, and 40-1 in the example of
On the other hand, in the above configuration, for example, the lengths of feeding lines connected to the respective feeding boards are designed to be the same in order to match the phases of the beams emitted from the respective radiation element arrays. Accordingly, for example, the lengths of the first feeder line 41 and the second feeder line 42 connected to the first distributor 52 may be designed to be the same. In this case, since the first feeding board 31 and the second feeding board 32 are of the same type to have the same phase, there is no phase difference between the two boards. If the first type feeding board and the second type feeding board have structures in which the feeding signals have a phase difference of 180 degrees therebetween according to the difference of the feeding patterns thereof, it is possible to considerably reduce the length of the feeding line connected to any one of the feeding boards to correspond to the phase difference of 180 degrees by properly differently designing the types of the feeding boards to be installed to the respective radiation element arrays. At this time, the reduced length of the feeding line may vary depending on a wavelength, a dielectric constant, and the like. For example, when the length of the first feeder line 41 is 100 mm, it is possible to reduce the length of the second feeding line 42 to 60 mm at 2 GHz, 40 mm at 2.6 GHz, and the like.
The construction of such a feeding line is capable of simplifying the complicated connection points of a plurality of feeding cables in the related art. Therefore, it is possible to improve the structural convenience in designing the antenna, to reduce the power loss according to the cable, and to meet the purpose of reducing the size and weight of the antenna.
The configurations and operations of omnidirectional antennas for a mobile communication service according the embodiments of the present invention may be implemented as described above. While specific embodiments have been described above, various modifications can be made without departing from the scope of the present invention.
For example, in the foregoing descriptions of the embodiments, it has been disclosed that the omnidirectional antennas or the radiation element arrays are formed by three radiation elements, which is a configuration for minimizing the size of the radiation element arrays and the omnidirectional antenna. If the size constraint is not large at the time of designing the radiation element arrays and the omnidirectional antenna, it is also possible to form one radiation element array or omnidirectional antenna by combining four or more radiation elements. In addition, in some cases, it is also possible to combine only two radiation elements. A design may be made while changing the number of radiation elements according to the use environment of the antenna. For example, in order to reduce the influence of the ripple that increases in proportion to a diameter of the antenna in the high frequency band, it is possible to reduce the number of radiation elements in the high frequency band and to increase the number of radiation elements in the low frequency band.
In the forgoing description, it has been described that the flexible printed circuit board on which the plurality of radiation elements are formed has a cylindrical shape. However, the flexible printed circuit board may have a polyhedral shape, besides the cylindrical shape. For example, the radiation element array 25 illustrated in
In addition, it has been described that the omnidirectional antenna according to the second embodiment described above has a structure in which four radiation element arrays are combined. However, a structure in which two radiation element arrays or six or more radiation element arrays are combined may also be possible. In addition, it has been described that the omnidirectional antenna according to the second embodiment has a structure in which the radiation element arrays having the same polarization are coupled to each other to be disposed adjacent to each other. However, the omnidirectional antenna may be configured in a form in which the radiation element arrays generating a +45 degree polarization and the radiation element arrays generating a −45 degree polarization are arranged alternately in the vertical direction.
In the above description, it has been described that the four radiation arms of each radiation element are designed to have the same shape and to be symmetrical with each other in order to simplify the manufacturing process and to shorten the manufacturing time. However, the four radiation arms may be implemented in different shapes. For example, the structure of the radiation pattern 110′ of the radiation element according to another embodiment of the present invention illustrated in
As described above, the omnidirectional antenna for a mobile communication service according to the present invention is capable of generating a +/−45 degree dual polarization while satisfying excellent omnidirectional radiation characteristics. Further, it is possible to implement the omnidirectional antenna with a small overall antenna size.
Number | Date | Country | Kind |
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10-2014-0109486 | Aug 2014 | KR | national |
This application is a continuation of U.S. application Ser. No. 15/438,397, filed on Feb. 21, 2017, which is a continuation of an International Application No. PCT/KR2015/007548 filed on Jul. 21, 2015, which claims priority to Korean Patent Application No. 10-2014-0109486 filed on Aug. 22, 2014, the entire disclosures of which are incorporated herein by reference.
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Entry |
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The Office Action from Korean Intellectual Property Office dated Mar. 9, 2020 for Korean Application No. 10-2014-0109486. |
Number | Date | Country | |
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20190296423 A1 | Sep 2019 | US |
Number | Date | Country | |
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Parent | 15438397 | Feb 2017 | US |
Child | 16429675 | US | |
Parent | PCT/KR2015/007548 | Jul 2015 | US |
Child | 15438397 | US |