The present invention relates to wireless communications, and more particularly, to antennas that incorporate multiple dipole arrangements in several frequency bands.
The introduction of new spectrum for cellular communications presents challenges for antenna designers. In addition to the traditional lowband (LB) and midband (MB) frequency regimes (617-894 MHz and 1695-2690 MHz, respectively), the introduction of C-Band and CBRS (Citizens Broadband Radio Service) provides additional spectrum of 3.4-4.2 GHz. Further, there is demand for enhanced performance in the C-B and, including 4×4 MIMO (Multiple Input Multiple Output as well as 8T8R (8-port Transmit, 8-port Receive) with beamforming.
The introduction of new and higher frequency bands, an addition to existing lowband and midband arrays, increases the packing density of radiators within macro antennas. Given the constraints of weight and wind loading, it is not desirable to increase the size of the antennas to accommodate dipole arrays of the new frequency bands, thereby by driving increased packing densities of radiators within existing radome designs. However, closer placement of dipoles of different frequency bands leads to performance degradation in the form of cross polarization and gain pattern contamination due to coupling and reradiation between frequency bands. This problem is particularly challenging in the case of RF interaction between midband and lowband dipoles, predominantly in the form of cross polarization. To complicate this challenge, there is considerable demand for a wide bandwidth in the midband (e.g., 1.7-2.7 GHz), which potentially aggravates the problem of cross polarization between the midband and the lowband.
Increasing packing density presents the considerable challenges, primarily from mutual coupling of dipoles of different frequency bands and the resulting cross polarization and other interference effects. An example of this is when radiation emitted by a lowband dipole causes excitation within portions of a nearby midband dipole, and the subsequent radiation emitted by the midband dipole couples back into the lowband dipole. The cross-coupled radiation may have a degraded polarization quality that, once coupled back into the lowband dipole, contaminates the isolation between the two radiated polarization states of the lowband dipole. This cross polarization interference can severely degrade beam quality and thus the performance of the antenna. As mentioned above, a conventional approach to preventing cross polarization is to distance the midband dipoles from the lowband dipoles, but this solution violates the requirement of minimizing antenna wind loading.
Accordingly, what is needed is a midband dipole design that offers strong performance, wide bandwidth while minimizing cross polarization.
An aspect of the present disclosure involves a radiator for a multiband antenna. The radiator comprises a crossed dipole plate having four folded dipole arms disposed thereon, the four folded dipole arms arranged in a cross pattern; four decoupling circuits disposed on the crossed dipole plate, each of the four decoupling circuits coupled to a corresponding folded dipole arm, each of the four decoupling circuits having a first capacitive pad, a second capacitive pad, and first inductive trace coupled to the first capacitive pad, wherein he first conductive pad, the second conductive pad, and the first conductive trace are disposed on a first side of the crossed dipole plate; and a pair of crossed balun stem plates mechanically coupled to the crossed dipole plate, each of the crossed balun stem plates having a pair of ground layers, each of the ground layers having a first conductive stem contact and a second conductive stem contact, wherein the first conductive stem contact is electrically coupled to the first capacitive pad and the second conductive stem contact is electrically coupled to the second capacitive pad.
As illustrated in
The operation of the folded dipole arms 205a/b/c/d on midband dipole plate 200 may be described as follows. Folded dipole arms 205a and 205b correspond to a −45 degree polarization, and folded dipole ams 205c and 205d correspond to a +45 degree polarization. An RF signal coupled to folded dipole arm 205a gets divided into two equal current flows 220a, one of which flows across connecting trace 305a to folded dipole arm 205c, and the other flows across connecting trace 305c to folded dipole arm 205d. Similarly, RF signal coupled to folded dipole arm 205b (which is the same RF signal as that applied to folded dipole arm 205a) gets divided into two equal current flows 220b, one of which flows across connecting trace 305b to folded dipole arm 205c, and the other flows across connecting trace 305d to folded dipole arm 205d. The superposition of current flows 220a and 220b through all four radiator arms 205a/b/c/d results in a −45 degree polarized radiated RF signal, whereby the RF emission components that are orthogonal to the −45 degree axis are mirrored on each side of the axis and are thus canceled via destructive interference, resulting in RF emission with polarization soleley along the −45 degree axis defined by folded dipole arms 205a/b.
The function is similar for the +45 degree polarized signal applied to folded dipole arms 205c and 205d. An RF signal coupled to folded dipole arm 205c gets divided into two equal current flows 220c, one of which flows across connecting trace 305a to folded dipole arm 205a, and the other flows across connecting trace 305b to folded dipole arm 205b. Similarly, RF signal coupled to folded dipole arm 205d (which is the same RF signal as that applied to folded dipole arm 205c) gets divided into two equal current flows 220d, one of which flows across connecting trace 305c to folded dipole arm 205a, and the other flows across connecting trace 305d to folded dipole arm 205b. The superposition of current flows 220c and 220d results in a +45 degree polarized radiated RF signal. The RF signal applied to folded dipole arms 205c/205d may be a completely different signal than the RF signal applied to folded dipole arms 205a/205b.
The specific shape of folded dipole arms 205a/b/c/d have features, such as gaps within the arms and the geometries of the outer edges of each arm, provides for good performance across the entire midband range of 1.7-2.7 GHz.
Each folded dipole arm 205a/b/c/d is coupled to a corresponding decoupling circuit 210, which minimizes common mode resonance with any nearby lowband dipole 110, further preventing cross polarization in the midband. The design of exemplary decoupling circuit 210 provides for resonance in the lowband (in particular, by resonating at λ/8, whereby λ is the wavelength of the lowband center frequency). By achieving lowband resonance in each exemplary decoupling circuit 210, each folded dipole arm 205a/b/c/d may operate with broad midband bandwidth without common mode resonance with the lowband dipoles 110, and thus prevent cross polarization.
Referring to the lower surface of the PCB of midband dipole plate 200, each decoupling circuit 210 has a first lower capacitance pad 440 that is disposed opposite first capacitance pad 405, and a second lower capacitance pad 445 that is disposed opposite second capacitance pad 410. As illustrated, lower inductive trace 435 is electrically coupled to first lower capacitance pad 440, lower second capacitance pad 445, and corresponding one of folded dipole arms 205a/b/c/d.
Further, as illustrated in
The addition of a second capacitance pad 410/445, and the meander length of inductive traces 415 and 435, provides sufficient capacitance and inductance to have the decoupling circuit 210 achieve resonance at λ/8 of the lowband center frequency. It does this while not affecting the tuning of the midband dipole assembly 105 so that it has strong performance from 1.7 GHz through 2.7 GHz. In the illustrated exemplary embodiment, the inductive length of decoupling circuit may be 84 mm, although it will be understood that different lengths and other such variations are possible and within the scope of the disclosure.
Electrically coupled to first capacitance pad 605 is a first inductive trace 615, which has a first meander path that terminates in a first via, through which first inductive trace 615 couples to a first lower inductive trace (not shown). Further, electrically coupled to second capacitance pad 610 is a second inductive trace 620, which has a second meander path that terminates in a second via, through which second inductive trace 620 couples to a second lower inductive trace (not shown). First capacitance pad 605 and second capacitance pad 610 may couple to their respective balun ground layers (not shown) via a solder pad similar to that disclosed above.
Conductively coupled to first lower capacitance pad 712 is a first lower inductive trace 715, which has a meander path that terminates at the first via through which it conductively couples to first inductive trace 615 disposed on the upper surface of the PCB. Similarly, conductively coupled to first lower capacitance pad 714 is a first lower inductive trace 720, which has a meander path that terminates at the second via through which it conductively couples to first inductive trace 620 disposed on the upper surface of the PCB.
The addition of a second capacitance pads 714 and 610, and the meander length of inductive traces 615/715 and 620/720, provides sufficient capacitance and inductance to have the decoupling circuit 610/710 achieve resonance at λ/8 of the lowband center frequency. It does this while not affecting the tuning of the second exemplary midband dipole plate so that it has strong performance from 1.7 GHz through 2.7 GHz. In the illustrated exemplary embodiment the inductive length of decoupling circuit may be 84 mm, although it will be understood that different lengths and other such variations are possible and within the scope of the disclosure.
In an exemplary embodiment, midband dipole plates 200/600 may be formed of a PCB material such as ZYF300CA-C, having a thickness of 30 mil, and the conductive elements and traces formed on the PCB according to the disclosure may be formed of Copper having a thickness of 1.4 mil. It will be understood that such materials and dimensions are exemplary, and that variations to these are possible and within the scope of the disclosure.
Although the disclosure describes a midband dipole assembly 105 as having the decoupling features that minimizes cross polarization due to common mode resonance with the lowband dipole 110, it will be understood that the disclosed features and advantages may pertain to corresponding dipoles of other frequency bands and ranges, provided that the decoupling features of the higher frequency dipole correspond to λ/8 of the frequency of the lower frequency dipole. Accordingly, the disclosed midband dipole plates are example embodiment of a crossed dipole plate according to the disclosure.
This application is a continuation of U.S. patent application Ser. No. 17/689,278, filed Mar. 8, 2022, which claims priority to U.S. Provisional Patent Application Ser. No. 63/158,028, filed Mar. 8, 2021, pending, which application is hereby incorporated by this reference in its entirety as if fully set forth herein.
Number | Date | Country | |
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63158028 | Mar 2021 | US |
Number | Date | Country | |
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Parent | 17689278 | Mar 2022 | US |
Child | 18118187 | US |