This application claims priority to Chinese Patent Application No. 201810246989.2, filed Mar. 23, 2018, the entire content of which is incorporated herein by reference.
The present invention belongs to the field of antenna technologies, and more specifically, relates to a balanced dipole unit and a broadband omnidirectional collinear array antenna.
With the development of mobile communication technologies, a broadband omnidirectional collinear array antenna with omnidirectional radiation function is widely used, such as the broadband omnidirectional collinear array antenna used in a wireless communication system, and in order to improve the radiation gain and efficiency of the broadband omnidirectional collinear array antenna, additional choke circuit such as a current regulator needs to be used in the broadband omnidirectional collinear array antenna, or a spacing between each radiating unit in the broadband omnidirectional collinear array antenna is increased, so as to improve the radiation gain and efficiency of the broadband omnidirectional collinear array antenna through reducing the current coupling between the units.
However, the method above of using the current regulator or increasing the spacing between each radiating unit in the broadband omnidirectional collinear array antenna may increase a length of the broadband omnidirectional collinear array antenna, and the method of using the current regulator or increasing the spacing between each radiating unit in the broadband omnidirectional collinear array antenna cannot reduce the influence of the metal supporting member in the broadband omnidirectional collinear array antenna on the broadband omnidirectional collinear array antenna. In addition, how to obtain a wider working bandwidth under a limited size is also one of the design difficulties of the broadband omnidirectional collinear array antenna.
The present subject matter provides a balanced dipole unit and a broadband omnidirectional collinear array antenna for reducing a length of the broadband omnidirectional collinear array antenna, thereby realizing a wider working bandwidth and reducing the interference of a metal supporting member in the broadband omnidirectional collinear array antenna to the broadband omnidirectional collinear array antenna. The technical solutions are as follows.
The present invention provides a balanced dipole unit, wherein the balanced dipole unit includes: a circuit carrier, a balanced dipole unit circuit, a feeder and a ground wire;
the balanced dipole unit circuits are symmetrically distributed on two planes of the circuit carrier; and
the feeder and the ground wire are connected to the balanced dipole unit circuit, and the feeder and the ground wire are symmetrically distributed in the balanced dipole unit.
It can be known from the technical solution above that the balanced dipole unit circuit in the balanced dipole unit is symmetrically distributed on two sides of the circuit carrier, and the feeder and ground wire in the balanced dipole unit are also symmetrically distributed, so that the balanced dipole unit has the symmetrical structure, and the principle of the symmetrical structure of the balanced dipole unit is the same as the differential design principle and the self-balancing principle in the circuit design, thereby reducing current coupling between the balanced dipole units and eliminating the need of using an additional choke circuit when the broadband omnidirectional collinear array antenna is formed by the balanced dipole unit, so as to greatly reduce the length of the broadband omnidirectional collinear array antenna, and the symmetrical structure of the balanced dipole unit may also reduce an interference of the metal supporting member, so as to reduce the influence of the metal supporting member on the broadband omnidirectional collinear array antenna when the broadband omnidirectional collinear array antenna is formed by the balanced dipole unit. In addition, by introducing an open slot into the balanced dipole unit circuit, the current distribution of the balanced dipole unit circuit can be changed to generate a plurality of resonance frequency points, and the working bandwidth of the broadband omnidirectional collinear array antenna formed by the balanced dipole unit is improved.
In order to more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the drawings to be used in the embodiments or the description of the prior art will be briefly introduced below. Obviously, the drawings in the following description merely indicate some embodiments of the present invention, and those skilled in the art can further obtain other drawings according to these drawings without going through any creative work.
In order to make the object, technical solution and advantages of the embodiments of the present invention clearer, the technical solution in the embodiments of the present invention will be described clearly and completely below with reference to the drawings in the embodiments of the present invention. Obviously, the embodiments described are a part of the embodiments of the present invention instead of all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by those skilled in the art on the premise of not going through creative works belong to the protection scope of the present invention.
The balanced dipole unit circuit 4 is symmetrically arranged on both sides of the circuit carrier 1 as shown in
It can be known from
In addition, the three antenna circuit lines themselves may also be a symmetrical circuit line in addition to the symmetrical distribution of the three antenna circuit lines, for example, in
It can be known from
One point needing to be explained here is that:
The feeder 2 and the ground wire 3 are symmetrically distributed in the balanced dipole unit, for example, the feeder 2 and the ground wire 3 are symmetrically distributed around a point in the circuit carrier 1, such as the center point in the circuit carrier 1 as a reference point, and in the embodiment, the feeder 2 and the ground wire 3 are connected to the balanced dipole unit circuit, for example, the feeder 2 is connected to a feed point in the balanced dipole unit circuit 4 for feeding for a radio frequency signal in the balanced dipole unit circuit 4, so that the radio frequency signal may be radiated when the balanced dipole unit is used as a radiating unit of the broadband omnidirectional collinear array antenna, the ground wire 3, and the ground wire 3 is connected to a short-circuit point in the balanced dipole unit circuit 4 for enabling the balanced dipole unit circuit 4 to be grounded through the ground wire 3. In
In the embodiment, the circuit carrier 1 may adopt, but is not limited to adopt a printed circuit board or a metal stamping part, when the circuit carrier 1 adopts the printed circuit board, the printed circuit board may be a dielectric substrate, and the balanced dipole unit circuit 4 may be printed on the printed circuit board by printing. When the circuit carrier 1 adopts the metal stamping part, the balanced dipole unit circuit 4 may be stamped on the metal stamping part by stamping. When the balanced dipole unit shown in
It can be known from the technical solution above that the balanced dipole unit circuit in the balanced dipole unit is symmetrically distributed on two sides of the circuit carrier, and the feeder and ground wire in the balanced dipole unit are also symmetrically distributed, so that the balanced dipole unit has a symmetrical structure, and the principle of the symmetrical structure of the balanced dipole unit is the same as the differential design principle and the self-balancing principle in the circuit design, thereby reducing current coupling between the balanced dipole units and eliminating the need of using an additional choke circuit when the broadband omnidirectional collinear array antenna is formed by the balanced dipole unit, so as to greatly reduce a length of the broadband omnidirectional collinear array antenna, and the symmetrical structure of the balanced dipole unit may also reduce an influence of a metal supporting member on the broadband omnidirectional collinear array antenna. In addition, the balanced dipole unit provided by the embodiment is modularized, so that when the balanced dipole unit constitutes the broadband omnidirectional collinear array antenna, the balanced dipole unit may be selected and assembled according to the antenna gain requirement, thereby saving manufacturing cost and reducing tuning time and assembly time.
In addition, for the balanced dipole unit provided by the embodiment above, the balanced dipole unit circuit 4 is provided with a plurality of open slots 7, and the plurality of open slots 7 arranged on the balanced dipole unit circuit 4 are symmetrically distributed on the circuit carrier 1. As shown in
The open slot 7 may be arranged on the balanced dipole unit circuit 4 through etching or other methods, and the symmetrically distributed open slot 7 may change the current distribution on the balanced dipole unit circuit 4, thus adding one to two new resonance frequency points based on an original resonance frequency point of the balanced dipole unit circuit 4, and increasing a working bandwidth of the broadband omnidirectional collinear array antenna formed by the balanced dipole unit through the original resonance frequency point and the new resonance frequency point, for example, through the design to the open slot 7, a frequency band covered by the working bandwidth of the broadband omnidirectional collinear array antenna may include but is not limited to a VHF (Very High Frequency) band of 138 MHz (megahertz) to 174 MHz, a UHF (Ultra High Frequency) band of 380 MHz to 512 MHz, and a cellular band of 746 MHz to 960 MHz. In the embodiment, a shape of the open slot 7 arranged on the balanced dipole unit circuit 4 is a shape of a Chinese character “”, an inverted T shape or a shape of a “±”, so as to increase new resonance frequency point.
It needs to be noted here that symmetrical distribution refers to the symmetrical distribution between the open slots 7, as shown in
In addition, the embodiment further provides a broadband omnidirectional collinear array antenna, which includes a metal supporting member, a non-metal fixing member and at least two balanced dipole units, wherein a structure of each balanced dipole unit in the at least two balanced dipole units is shown in
A number of the balanced dipole units included in the broadband omnidirectional collinear array antenna may be determined according to the antenna gain requirement of the broadband omnidirectional collinear array antenna, after selecting the balanced dipole unit that meets the antenna gain requirement, the selected balanced dipole unit is assembled, for example, when the structure of the balanced dipole unit in the broadband omnidirectional collinear array antenna is shown in
When the broadband omnidirectional collinear array antenna is formed by the balanced dipole unit, a spacing between each balanced dipole unit in the broadband omnidirectional collinear array antenna is the same or different, that is, when the broadband omnidirectional collinear array antenna is constituted, two adjacent balanced dipole units may be separated through a preset distance, so that the spacing between each balanced dipole unit in the broadband omnidirectional collinear array antenna is the same, and the preset distance may be determined according to a working wavelength of the broadband omnidirectional collinear array antenna, for example, the present distance may be, but is not limited to 0.75 times the working wavelength of the broadband omnidirectional collinear array antenna. Alternatively, when the broadband omnidirectional collinear array antenna is constituted, two adjacent balanced dipole units may be separated through different distances, and it needs to be noted here that if at least a spacing between the two adjacent balanced dipole units is different from a spacing between other adjacent balanced dipole units, the spacing between each balanced dipole unit in the broadband omnidirectional collinear array antenna is considered to be different.
When the structure of the balanced dipole unit in the broadband omnidirectional collinear array antenna is shown in
When the broadband omnidirectional collinear array antenna is formed by the balanced dipole unit, an arrangement method of the circuit carriers in each balanced dipole unit relative to the metal supporting member of the broadband omnidirectional collinear array antenna may be that: the circuit carriers in each balanced dipole unit are symmetrically distributed around the metal supporting member of the broadband omnidirectional collinear array antenna or are asymmetrically on at least two sides of the metal supporting member of the broadband omnidirectional collinear array antenna. That is to say, the circuit carrier in a part of the balanced dipole units constituting the broadband omnidirectional collinear array antenna and the circuit carrier in the remaining part of the balanced dipole units constituting the broadband omnidirectional collinear array antenna are arranged on different sides of the metal supporting member of the broadband omnidirectional collinear array antenna. For example, the circuit carrier in a part of the balanced dipole units is arranged on a first side of the metal supporting member of the broadband omnidirectional collinear array antenna, and the circuit carrier in the remaining part of the balanced dipole units is arranged on a second side opposite to the first side of the metal supporting member of the broadband omnidirectional collinear array antenna, and when the circuit carrier is arranged, all the circuit carriers may be symmetrically or asymmetrically distributed on the metal supporting member of the broadband omnidirectional collinear array antenna.
For all the circuit carriers arranged on the metal supporting member of the broadband omnidirectional collinear array antenna, if two adjacent circuit carriers are symmetrically distributed on the metal supporting member of the broadband omnidirectional collinear array antenna, all the circuit carriers are considered to be symmetrically distributed on the metal supporting member of the broadband omnidirectional collinear array antenna, and in all the circuit carriers arranged on the metal supporting member of the broadband omnidirectional collinear array antenna, if at least one circuit carrier and the remaining circuit carriers, such as the adjacent circuit carrier in the remaining circuit carriers are asymmetrically distributed, all the circuit carriers may be considered to be asymmetrically distributed on the metal supporting member of the broadband omnidirectional collinear array antenna.
In the embodiment, a feasible method for arranging the circuit carriers in each balanced dipole unit around the metal supporting member of the broadband omnidirectional collinear array antenna is that: the circuit carriers in each balanced dipole unit are alternately arranged on at least two sides of the metal supporting member of the broadband omnidirectional collinear array antenna, and the so-called alternate arrangement on at least two sides of the metal supporting member of the broadband omnidirectional collinear array antenna means that the circuit carriers in the two adjacent balanced dipole units in the broadband omnidirectional collinear array antenna are located on different sides of the metal supporting member of the broadband omnidirectional collinear array antenna. As shown in
Specifically, in
Certainly, in additional to the method shown in
For another example, the method shown in
If a first balanced dipole unit in the four balanced dipole units of the same group arranged on the metal supporting member of the broadband omnidirectional collinear array antenna is used for reference, the remaining three balanced dipole units respectively rotate by 90 degrees, 180 degrees and 270 degrees (all the balanced dipole units rotate counterclockwise or clockwise) relative to the first balanced dipole unit, so that the circuit carriers in the balanced dipole units may be alternately arranged on four sides of the metal supporting member of the broadband omnidirectional collinear array antenna, and the angle difference between the circuit carriers in two adjacent balanced dipole units and the metal supporting member of the broadband omnidirectional collinear array antenna is 90 degrees, so that the broadband omnidirectional collinear array antenna may radiate in four directions.
Certainly, when the circuit carriers in each balanced dipole unit are arranged around the metal supporting member of the broadband omnidirectional collinear array antenna, the circuit carriers may also be arranged around one side or three sides of the metal supporting member of the broadband omnidirectional collinear array antenna, when the circuit carriers are arranged around one side, the circuit carriers may be arranged symmetrically or asymmetrically on one side, and when the circuit carriers are arranged around three sides, the circuit carriers may be arranged with reference to the method shown in
When the broadband omnidirectional collinear array antenna is formed by the balanced dipole unit, another arrangement method of the circuit carriers in each balanced dipole unit relative to the metal supporting member of the broadband omnidirectional collinear array antenna may be that: the metal supporting member of the broadband omnidirectional collinear array antenna includes at least two supporting portions, two adjacent supporting portions in the at least two supporting portions are connected through a metal part, each supporting portion corresponds to at least one balanced dipole unit in the broadband omnidirectional collinear array antenna, and orientations of the balanced dipole units corresponding to different supporting portions are different. The following description takes the broadband omnidirectional collinear array antenna shown in
As shown in
When the broadband omni-directional collinear array antenna is constituted based on the method shown in
It shall be noted here that the broadband omnidirectional collinear array antenna shown in
In the broadband omnidirectional collinear array antenna above, the broadband omnidirectional collinear array antenna provided in the embodiment further includes a signal feeder and a power divider, wherein the signal feeder is configured to feed a radio frequency signal, and the power divider is configured to divide the radio frequency signal to each balanced dipole unit. That is to say, the radio frequency signal is transmitted to each balanced dipole unit of the broadband omnidirectional collinear array antenna through the power divider in the broadband omnidirectional collinear array antenna, and the radio frequency signal transmitted to each balanced dipole unit is fed through the signal feeder, wherein the signal feeder is connected to the feeder in each balanced dipole unit to feed the radio frequency signal received by the balanced dipole unit through the feeder in the balanced dipole unit, thereby radiating the radio frequency signal through the balanced dipole unit.
For the metal supporting member of the broadband omnidirectional collinear array antenna, a first end of the metal supporting member of the broadband omnidirectional collinear array antenna is provided with a feed port for connecting the signal feeder, so as to access the signal feeder through the feed port; and a second end of the metal supporting member of the broadband omnidirectional collinear array antenna is provided with a lightning protection element, so that the metal supporting member of the broadband omnidirectional collinear array antenna can not only be used as a support for the collinear array antenna, but also be used as a part of a lightning protection circuit in the broadband omnidirectional collinear array antenna to prevent lightning strike on the broadband omnidirectional collinear array antenna and protect the broadband omnidirectional collinear array antenna. For example, the broadband omnidirectional collinear array antenna can withstand a lightning current of 150 kA (pulse: 10/350 μs) through the lightning protection element, which meets the requirement of Class-II lightning protection according to provisions of parts 1 to 4 of IEC 62305 and VDE 0855-300 standard.
In order to explain the effect of the broadband omnidirectional collinear array antenna provided in the embodiment, an actual test result diagram of a return loss is provided.
It needs to be stated that the various embodiments in the description are described in a progressive manner, each embodiment focuses on the differences from other embodiments, and the same and similar parts among the various embodiments can be seen from each other.
Finally, it further needs be noted that in the text, relational terms such as first and second are only used to distinguish one entity or operation from another entity or operation, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Moreover, the terms “comprise”, “contain” or any other variations thereof are intended to cover a non-exclusive inclusion, so that a device includes not only those elements but also other elements not expressly listed, or further includes inherent elements to the device. Without further restrictions, the elements defined by the statement “comprise one . . . ” do not exclude the existence of other identical elements in the included device.
The foregoing description of the disclosed embodiments enables those skilled in the art to achieve or use the present invention. The various modifications to these embodiments will be apparent to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of the present invention. Therefore, the present invention will not be limited to these embodiments shown herein, and shall have a widest scope consistent with the principles and novel features disclosed herein.
The foregoing is merely the preferred embodiments of the present invention, and it shall be noted that those skilled in the art may further make a plurality of improvements and decorations without departing from the principle of the present invention, and these improvements and decorations shall also fall within the protection scope of the invention.
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