The present invention relates to antennas for wireless communications, and more particularly, to multiband antennas that have low band and high band dipoles located in close proximity.
There is considerable demand for cellular antennas that can operate in multiple bands and at multiple orthogonal polarization states to make the most use of antenna diversity. A solution to this is to have an antenna that operates in two orthogonal polarization states in the low band (LB) (e.g., 698-960 MHz) and in two orthogonal polarization states in the high band (HB) (e.g., 1.695-2.7 GHz). A typical set of orthogonal polarization states includes +/−45 deg. There is further demand for the antenna to have minimal wind loading, which means that it must be as narrow as possible to present a minimal cross sectional area to oncoming wind. Another demand is for an antenna to have a fast rolloff gain pattern in both the High Band (HB) and Low Band (LB) to mitigate inter-sector interference. Conventional antennas have gain patterns with considerable side and rear lobes. These antennas are typically mounted on a single cell tower, each covering a different sector, which results in the side and rear lobes of their respective gain patterns overlapping, causing interference in the overlapping gain regions. Therefore it is desirable for an antenna to have a fast-rolloff gain pattern, whereby beyond a given angle (e.g., 45° or 60°), the antenna gain pattern falls off rapidly, thereby minimizing overlapping gain patterns between multiple sector antennas mounted on a single cell tower. Further, interference between the LB and HB dipoles can contaminate their respective gain patterns, thus degrading the performance of the antenna.
The need for both a compact array face and a fast rolloff gain pattern causes a conflict in objectives because the best way to achieve a fast rolloff gain pattern is to broaden the array face of the antenna, and broadening the antenna array face increases wind loading. Conversely, the more closely LB and HB dipoles are spaced together on a single array face, the more they suffer from interference whereby transmission in either the HB or the LB is respectively picked up by the LB and HB dipoles, causing coupling and re-radiation that contaminates the gain pattern of the transmitting band.
This problem can be solved with dipoles that are designed to be “cloaked”, whereby they radiate and receive in the band for which they are designed yet are transparent to the other band that is radiated by the other dipoles sharing the same compact array face.
Cloaked dipoles are typically divided into conductive segments that are coupled by intervening inductor and/or capacitor structures. The conductive segments have a length that is less than one half wavelength of the RF energy (cloaked wavelength) for which induced current is to be prevented. The inductor and/or capacitor structures are tuned so that they resonate at and above this cloaked wavelength, being substantially open circuited above the cloaked wavelength and substantially short circuited below the cloaked wavelength.
LB dipoles are typically cloaked to prevent HB induced current from occurring in the LB dipole conductors. Otherwise, HB energy emitted by the HB dipole would induce a current in the LB dipole, which would subsequently re-radiate and interfere with the HB gain pattern.
As mentioned above, cloaked dipole structures involve inductors and/or capacitors located between conductive elements within the dipole arm. These structures may be complex and require additional PCB and metal layers, adhesives, and ancillary components that must be attached to or integrated into the dipole structure. As such, cloaked dipoles can be complicated, expensive and time consuming to manufacture, and may incur reliability issues.
Accordingly, there is a need for a multiband antenna, with a minimal array face but with strong multiband performance (e.g., clean gain patters with minimal interference and fast rolloff), and that has LB dipoles that are simple and easy to manufacture.
Accordingly, the present invention is directed to a low cost high performance multiband cellular antenna with cloaked monolithic metal dipole that obviates one or more of the problems due to limitations and disadvantages of the related art.
In an aspect of the present invention, a multiband antenna comprises a reflector plate, a plurality of high band dipoles configured to radiate RF energy in a high band, and a plurality of low band dipoles configured to radiate RF energy in a low band. Each of the low band dipoles has a plurality of low band dipole arms, each low band dipole arm being formed of a single piece of metal the single piece of metal having a plurality of inductor structures. The inductor structures each having a dimension that makes the inductor structure resonate at frequencies corresponding to the high band, hindering the low band dipole from re-radiating RF energy in the high band, and that enables the inductor structure to radiate RF energy in the low band.
In another aspect of the present invention, a multiband antenna comprises a reflector plate, a plurality of high band configured to radiate RF energy in a high band, and a plurality of low band dipoles configured to radiate RF energy in a low band. Each of the low band dipoles has a plurality of low band dipole arms, each low band dipole arm being formed of a single piece of metal and having a plurality of inductor structures in the low band dipole arm, wherein the inductor structures hinder induced current corresponding to RF energy radiated by at least one of the plurality of high band dipoles.
Further embodiments, features, and advantages of low cost high performance multiband cellular antenna with cloaked monolithic metal dipole, as well as the structure and operation of the various embodiments of the low cost high performance multiband cellular antenna with cloaked monolithic metal dipole, are described in detail below with reference to the accompanying drawings.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only, and are not restrictive of the invention as claimed.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiment(s) of the low cost high performance multiband cellular antenna with cloaked monolithic metal dipole described herein, and together with the description, serve to explain the principles of the invention.
Reference will now be made in detail to embodiments of the low cost high performance multiband cellular antenna with cloaked monolithic metal dipole with reference to the accompanying figures
Array face 100 further includes a plurality of high band (HB) dipoles 120. Each HB dipole 120 has an HB dipole stem 125 through which HB dipole 120 is mechanically and electrically coupled to an HB feedboard 129. HB dipole 120 further includes a passive HB radiator plate 127.
Further illustrated in
There is a tradeoff. Generally, locating HB dipole 120 closer to reflector plate 105 reduces the bandwidth of HB dipole 120. However, there is a “sweet spot” at an elevation of 0.93″ whereby the current LB induced is effectively mitigated and the bandwidth-limiting effects of proximity to reflector plate 105 are not yet prevalent. The elevation of HB dipole 120 may vary around 0.93″ by as much as +/−⅛″ without significantly degrading the performance of the HB dipole 120. Any lower elevation beyond this tolerance (closer to the reflector plate 105) results in diminished bandwidth. Any higher elevation beyond this tolerance incurs increased induced current from the LB dipole 110.
An advantage of this arrangement is that, at an elevation of approximately 0.93″, HB dipole 120 need not have any cloaking structures (inductors and/or capacitors embedded among the dipole conductive elements), which would increase the complication and cost of HB dipole 120. This is because the majority of the LB induced current occurs in the HB dipole stem 125 and not in the radiators of HB dipole 120. Accordingly, mitigating induced current in HB dipole stem 125 effectively addresses the problem, and cloaking structures in the radiators of HB dipole 120 are unnecessary.
Further illustrated in
Variations to fast rolloff array face 200 are possible and within the scope of the disclosure. For example, instead of the illustrated 1-2-1-2-1 LB dipole configuration, the LB dipoles 110 may be arranged in a 2-1-2-1-2 configuration. This configuration would have a similar gain pattern and performance to the 1-2-1-2-1 configuration, but would incur additional cost because it has an additional LB dipole 110. In a further variation, each unit block may be identical and have the two LB dipoles adjacent along the azimuth axis, in a 2-2-2-2-2 arrangement. This antenna array face would have a tighter azimuthal gain pattern due to the enhanced array factor, with an approximate 45-50 degree azimuthal beamwidth. Further, the antenna array face may have more than five unit blocks, as would be the case with a 6′ or 8′ antenna. It will be readily apparent that such variations are possible and within the scope of the disclosure.
Each of the on-axis slots 320 and orthogonal slots 330 are openings in the structure of LB dipole 310, forming a plurality of inductor structures in the remaining metal surrounding the slots. Each inductor structure functions as an open circuit at HB frequencies (e.g., 1.695-2.7 GHz) and functions as a short circuit at LB frequencies (e.g., 698-960 MHz). Given the orientations of on-axis slots 320 and orthogonal slots 330, HB RF energy emitted by HB dipole 120 in the +45 degree polarization does not induce a current in LB dipole arms 310 because the correspondingly oriented slots function as inductors that render LB dipole 110 transparent to the +45 degree polarized RF energy. The same is true for the other emitted polarization state, whereby HB RF energy emitted by HB dipole 120 in the −45 degree polarization also does not induce a current in LB dipole arms 310 due to the other slots (orthogonal to the slots corresponding to the +45 degree polarization orientation) in LB dipole arms 310, rendering LB dipole 110 transparent to the −45 degree polarized RF energy.
In an exemplary embodiment, the diameter of the roll of tubular LB dipole arm 710 may be substantially 0.5″, with a 3/32″ gap between the longitudinal outer edges of the dipole arm. Variations to the tubular LB dipole 700 are possible and within the scope of the disclosure. For example, one variation of LB tubular dipole 700 may involve a broader diameter curvature of the tube shape, and thus with a wider gap between the longitudinal edges of LB tubular dipole arms 710. However, the lessening the curvature of the tubular structure diminishes the benefits of scattering incurred by the curved shape, thus diminishing the inhibited interference for the HB dipole 120. Reducing the diameter of curvature yields improved performance, but it then becomes more of a challenge to maintain a consistent gap between the longitudinal edges of the dipole arms. Another variation within the scope of the disclosure is to have tubular LB dipole arms 710 formed as tubes with no gap. This may improve performance. However, to manufacture this variation of tubular LB dipole arms 710, instead of stamping and bending a single piece of sheet aluminum (for example), one could start with an aluminum tube and mill out the slots described above. This variation to tubular LB dipole 710 would likely increase the cost of manufacturing.
The embodiment illustrated in
As illustrated, it will be apparent that the dipole arms 805 of LB dipole 800 are longer and narrower than those of the other LB dipoles disclosed above. Having the dipole arms 805 longer improves its LB performance, and having the dipole arms 805 narrower reduces interference with the HB dipoles that are in the vicinity of the array face. The sawtooth structure of LB dipole arms 805 provide improved cloaking over the other embodiments, due to the fact that the structure reduces the pathways by which HB transmissions might excite the metal in the LB dipole. Having a narrower dipole arm 805 generally reduces the LB bandwidth, relative to a wider dipole arm. This may be compensated for by raising the LB dipole 800 to a height of approximately 85 mm, and by tuning the balun circuit on the dipole stem. It will be understood that the act of tuning a blun circuit is known to the art and need not be described in further detail.
While various embodiments of the present invention have been described above, it should be understood that they have been presented by way of example only, and not limitation. It will be apparent to persons skilled in the relevant art that various changes in form and detail can be made therein without departing from the spirit and scope of the present invention. Thus, the breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments but should be defined only in accordance with the following claims and their equivalents.
This application is a Continuation of application Ser. No. 16/758,094, filed Apr. 22, 2020, pending, which is a 371 National Stage Application of PCT/US2018/057453, filed Oct. 25, 2018, expired, which claims the benefit of U.S. Provisional Patent Application Ser. No. 62/577,407, filed Oct. 26, 2017, which applications are hereby incorporated by this reference in their entireties for all purposes as if fully set forth herein.
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Number | Date | Country | |
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20220037804 A1 | Feb 2022 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 16758094 | US | |
Child | 17494329 | US |