TWM538255U - Low profile omnidirectional antennas - Google Patents

Abstract

Disclosed are exemplary embodiments of a low profile wideband and/or multiband omnidirectional antennas. In an exemplary embodiment, an antenna generally includes a radiator and a ground plane. The ground plane may include a slanted surface along or defining an edge portion of the ground plane. The slanted surface may be configured to be operable for reducing null at azimuth plane to thereby allow the antenna to have more omnidirectional radiation patterns for the azimuth plane. In another exemplary embodiment, an antenna generally includes a substrate, a radiator along the substrate, and electrically-conductive tape or foil defining at least part of a ground plane. The electrically-conductive tape or foil is coupled to a ground of the radiator via proximity coupling and electrically insulated by masking of the substrate.

Description

Low profile omnidirectional antenna

This description relates to a low profile omnidirectional antenna.

Cross-references to related applications

The present application claims the benefit of priority to the Japanese Patent Application No. PI2016701614, filed on May 5, 2016, and its priority.

The present application also claims the rights and priority of U.S. Patent Application Serial No. 15/241,890, which is incorporated herein by reference.

The entire disclosure of the above application is hereby incorporated by reference.

This paragraph provides background information related to the contents of this document, which is not necessarily prior art.

For cellular network applications within the building, some applications require a single-input single-output (SISO) antenna that has an ultra-low profile and is aesthetically pleasing to the building roof. Traditionally, this type of antenna has been designed to have a single pole piece parallel to the roof that has a large range of zero values and a poor omnidirectional shape in the azimuthal plane.

An embodiment of the present application claims an antenna comprising: a radiator; and a ground plane including an inclined surface along the ground plane An edge portion or to define the edge portion, whereby the inclined surface is configured to be operative to reduce a range of zero values in the azimuth plane, thereby allowing the antenna to be more omnidirectional in the azimuth plane Radiation pattern.

Another embodiment of the present application is directed to an antenna comprising: a substrate; a radiator along the substrate; and a conductive tape or foil defining at least a portion of a ground plane, The conductive tape or foil is coupled to the ground of the radiator via a proximity coupling and is electrically insulated by a mask of the substrate.

100‧‧‧ (omnidirectional SISO) antenna

104‧‧‧Blocks

108‧‧‧ radome

112‧‧‧floor

116‧‧‧Printed circuit board

120‧‧‧ Ground plane

124‧‧‧radiator

128‧‧‧Threaded short column features

132‧‧‧Feed cable

136‧‧‧ openings

140‧‧‧Bucks

144‧‧‧ notch

148‧‧‧Hot-melt column

152‧‧‧ openings

156‧‧ ‧ ribs

162‧‧‧ sloping surface

164, 166‧‧‧ horizontal section

168‧‧‧Another part

170, 172‧‧‧ grooves

174‧‧‧Feeding grounding point

176‧‧‧main or first radiating element

178, 180‧‧‧ High-frequency radiating elements/arms

181, 183‧‧ ‧ gap

182‧‧‧Microstrip line

184‧‧‧ Feeding points

186‧‧‧ hole

216‧‧‧Printed circuit board

220‧‧‧ Ground plane

224‧‧‧radiator

232‧‧‧ cable

262‧‧‧ sloping surface

264‧‧‧ horizontal part

270, 272‧‧ ‧ grooves

276‧‧‧main or first radiating element

278, 280‧‧ ‧ high frequency radiating elements / arm

282‧‧‧Microstrip line

284‧‧ Feeding points

300‧‧‧ (omnidirectional SISO) antenna

304‧‧‧Blocks

316‧‧‧Printed circuit board

320‧‧‧Conductive tape/foil

322‧‧‧Part/ground

324‧‧‧radiator

362‧‧‧Sloping surface

364, 368‧‧‧ horizontal section

370, 372‧‧‧ grooves

376‧‧‧main or first radiating element

378, 380‧‧‧ High-frequency radiating elements/arms

382‧‧‧Microstrip line

384‧‧‧ Feeding points

Section 388‧‧‧

390‧‧‧Coaxial Feed Cable

400‧‧‧(omnidirectional SISO) antenna

412‧‧‧floor

416‧‧‧Printed circuit board

428‧‧‧Threaded short column features

432‧‧‧feed cable

492‧‧‧ dielectric spacer

494‧‧‧ hole

496‧‧‧Oval

The drawings are intended to be illustrative of the preferred embodiments, and are not intended to limit the scope of the invention.

1 is a perspective view of a wideband/multipleband low profile omnidirectional antenna in accordance with an exemplary embodiment; FIGS. 2A and 2B are perspective rear side views of a prototype of the antenna shown in FIG. 1. And a stereo front side view, wherein the antenna comprises a transparent radome (Fig. 2B) and a transparent bottom plate or support member (Fig. 2A); Fig. 3 is an exploded perspective view of the antenna shown in Figs. 2A and 2B, Also illustrated is a printed circuit board positioned between the radome and the backplane; FIG. 4 is a rear side view of the antenna shown in FIG. 2A without the backplane and illustrating the ground plane and along the printed circuit board a patch on the rear side of the (PCB) and a feed cable coupled to (eg, soldered, etc.) to the ground plane; FIG. 5 is a front side view of the printed circuit board shown in FIG. Which exemplifies a radiator along the front side of the printed circuit board; Figure 6 is a perspective view of the bottom plate and radome shown in Figure 3 after the bottom plate is coupled to the radome; Figure 7 is a lower perspective view of the bottom plate and radome shown in Figure 6; Figure 8 is a perspective view of the printed circuit board shown in Figure 4, illustrating the ground plane and the block along the rear side of the printed circuit board; Figure 9 is the printing shown in Figure 5. Another front side view of the circuit board illustrating the radiator along the front side of the printed circuit board; FIGS. 10, 11 and 12 are perspective rear side views of the printed circuit board shown in FIGS. 8 and 9. , a perspective side view and a perspective front side view, wherein an exemplary dimension (in millimeters) is provided for illustrative purposes only in accordance with an exemplary embodiment; FIG. 13 is a fitment to FIG. 1 in accordance with another exemplary embodiment. A perspective view of a printed circuit board used in the antenna shown in FIG. 3, wherein the printed circuit board includes a radiator and a ground plane along the opposite front and rear sides of the printed circuit board, but does not include along The back side of the printed circuit board 1A and 14B are a perspective rear side view and a front front side view of the printed circuit board shown in Fig. 13, with exemplary dimensions provided for illustrative purposes in accordance with an exemplary embodiment. (in millimeters); Figure 15A is an exemplary line graph of voltage standing wave ratio (VSWR) versus frequency in megahertz (MHz), which is for having as shown in Figures 14A and 14B a prototype antenna of the printed circuit board as shown in Figures 1 to 3, which does not include a block along the rear side of the printed circuit board; Figure 15B is an exemplary line graph of voltage standing wave ratio (VSWR) against frequency in megahertz (MHz), which is for a printed circuit board as shown in Figures 10 through 12 A prototype antenna shown in FIGS. 1 to 3 includes a block along the rear side of the printed circuit board; FIGS. 16 to 81 are diagrams illustrating radiation patterns at various frequencies (azimuth plane, Phi 0 degree plane and Phi 90 degree plane), this measurement is for a prototype antenna as shown in FIGS. 1 to 3 having a printed circuit board as shown in FIGS. 14A and 14B, which does not include Blocks along the back side of the printed circuit board; Figures 82 and 83 are passive intermodulation level (PIM) relative carriers (dBc) in decibels versus frequency in megahertz (MHz) Exemplary line diagram for a prototype antenna as shown in Figures 1 through 3 having a printed circuit board as shown in Figures 14A and 14B, which does not include along the printed circuit a block on the back side of the board and showing two transmitted carriers (20 watts each) at 728MHz to 757MHz and 1930MHz to 1990MHz PIM (IM3) performance at the transmission (Tx) frequency; Figures 84 through 137 are examples of radiation patterns (azimuth plane, Phi 0 degree plane, and Phi 90 degree plane) at various frequencies, this measurement is for a prototype antenna as shown in FIGS. 1 to 3 of the printed circuit board as shown in FIGS. 10 to 12, comprising a block along the rear side of the printed circuit board; FIG. 138 and FIG. 139 is an exemplary line graph of passive intermodulation variable level (PIM) relative carrier (dBc) in decibels in frequency in megahertz (MHz). This measurement is for having as shown in Figure 10 to Figure A prototype antenna of the printed circuit board shown in FIG. 1 as shown in FIGS. 1 to 3, which comprises a block along the rear side of the printed circuit board, and which is shown Two transmitted carriers (20 watts each) of PIM (IM3) performance at respective transmission (Tx) frequencies of 728 MHz to 757 MHz and 1930 MHz to 1990 MHz; FIG. 140 is a diagram illustrating another exemplary embodiment in accordance with another exemplary embodiment A wideband/multipleband low profile omnidirectional SISO antenna comprising a radiator along a printed circuit board and a conductive tape or foil, wherein the conductive tape or foil is coupled to the radiation via an approximately coupling action One of the devices is grounded and electrically insulated by the mask of the printed circuit board itself; Figure 141 is an exemplary dimension (in millimeters) that provides a conductive tape or foil as shown in Figure 140 and Angle (in degrees), which is set in accordance with an exemplary embodiment for illustrative purposes only; Figure 142 is an exemplary line of voltage standing wave ratio (VSWR) versus frequency in megahertz (MHz) The measurement is for a prototype having an antenna as shown in FIG. 140; FIG. 143 is an exploded perspective view of a wideband/multi-frequency low profile omnidirectional SISO antenna in accordance with another exemplary embodiment. View, one of them A dielectric spacer is positioned between the backplane or support member and a printed circuit board and is generally located adjacent an opening of the threaded stub of the backplane; and FIG. 144 is as shown in FIG. A partial cross-sectional side view of the antenna, after the printed circuit board and the dielectric spacer have been positioned in an inner enclosed space, the inner enclosed space is cooperatively defined between the bottom plate and a radome.

Throughout the several views in the drawings, corresponding component symbols indicate corresponding components.

The illustrative embodiments will now be described more fully with reference to the accompanying drawings.

Disclosed herein are exemplary embodiments of wideband and/or multi-frequency low profile omnidirectional SISO antennas. In some exemplary embodiments, the antenna is configured for wideband operation such that the antenna can operate over a wide frequency range (eg, from about 600 MHz to about 3800 MHz, spanning most of the Long Term Evolution (LTE) band, etc.). In other exemplary embodiments, the antenna is configured for multi-frequency operation such that the antenna can operate in at least one first frequency range (eg, from about 698 MHz to about 960 MHz, etc.), and different from the first frequency range A second frequency range (eg, from about 1350 MHz to about 1525 MHz, from about 1690 MHz to about 3800 MHz, from about 1350 MHz to about 3800 MHz, etc.). For example: the antenna can operate in a first frequency range from about 698 MHz to about 960 MHz, in a second frequency range from about 1350 MHz to about 1525 MHz, and a third in from about 1690 MHz to about 3800 MHz. Within the frequency range. In other possible exemplary embodiments, the antenna may cover more than the frequency range described above (e.g., 600 to 6000 MHz, etc.) with a trade-off in the zero value range of the radiation pattern.

In an exemplary embodiment, the antenna includes a radiator within an interior space that is cooperatively defined between a radome and a floor or support member. The base plate may include a threaded stud feature (broadly speaking: a mounting feature or fixture) for mounting the antenna to a roof (broadly speaking: a mounting surface). The radiator may comprise a printed circuit board radiator, an imprinted radiator, a flexible printed circuit board radiator, combinations of the foregoing, and the like. For example: the antenna can be along a first and second side (or front or back) of a printed circuit board (broadly speaking: a substrate) It contains a radiator and a ground plane (broadly speaking: a grounding element).

In an exemplary embodiment, the antenna may include asymmetric arms (eg, arms 120 and 124 along opposite sides of a printed circuit board as shown in Figures 8 and 9, etc.), and thus are not A typical dipole antenna with a symmetrical arm. A longer/larger asymmetric arm may be referred to as a ground plane, while another asymmetric arm may be referred to as a radiator.

The creators of the present application have recognized that several factors play an important role in a horizontal planar asymmetric dipole antenna as described herein to have a reduced range of zero values and more in the azimuthal plane. Radial pattern of the directional type: 长度 the ratio of the length between the radiator and the ground plane; 边缘 the angle of the ground plane relative to the edge of the radiator; the position of the feed point; and the arm of the radiator The length of one.

The creators of the present application have also recognized that there are several factors for a horizontal planar asymmetric dipole antenna that maintains a reduced zero range and a more omnidirectional radiation pattern in the azimuthal plane. Broadening the bandwidth of the antenna: 宽 the wide arm or ground plane of the antenna; the coupling between the arm and the ground plane; ̇ via the edge of the radiator that overlaps one of the edges of the radiator The impedance matching of a groove; a groove used near the welding position of the feed cable; and the width and length of the transmission line.

The creators of the present application have further recognized that there are several factors that electrically lengthen the antenna when it has a lower frequency option to cover frequencies starting at 600 MHz without significantly increasing the antenna size: ̇ slightly elongated To define the trace of this ground plane; 延长 extend the radiator via a suspension-loaded or closely-connected trace (broadly: a block) to increase its electrical length; and ̇ has an additional dielectric load, which It is provided by at least one rib at a predetermined or some position in or below the radome.

The creators of the new application have additionally recognized that there are several factors that reduce the risk of PIM levels: 取代 replacing a fixed connector with a tail-flap coaxial cable, which is less free to match this antenna; and ̇ 馈送The groove(s) at the grounding point to reduce the soldering surface.

Accordingly, embodiments of the antennas described herein may have or provide one or more of the following features or advantages over conventional dipole antennas. For example, a broadband and/or multi-frequency low profile omnidirectional SISO antenna as described herein may have fewer zero value ranges at the azimuthal plane than a conventional bipolar device. Compared with other conventional antennas, a low profile broadband and/or multi-frequency omnidirectional SISO antenna described herein can also have a wide bandwidth at an azimuth plane, enabling a stable low PIM product. And/or can have a low profile. Moreover, an exemplary embodiment may include one or more features to achieve or achieve a low PIM level. For example: some exemplary embodiments may have an improved or low PIM level due to a groove (in a broad sense: opening) near the feed ground point for this feed cable The line is to lower this soldering surface.

Referring now to the drawings, Figures 1, 2A and 2B illustrate an exemplary embodiment of an omni-directional SISO antenna 100 in which one or more aspects of the present disclosure are present. As described herein, this antenna 100 can be configured for wideband operation or multi-frequency operation depending on whether the antenna 100 includes the block 104 shown in Figures 4 and 8. When the antenna 100 includes the block 104, the antenna 100 can be configured to operate over a wide frequency range (e.g., from about 600 MHz to about 3800 MHz, etc.). When the antenna 100 does not include the block 104, the antenna 100 can be configured to operate in a plurality of frequency ranges (e.g., a first frequency range from about 698 MHz to about 960 MHz, from about 1350 MHz to about 1525 MHz). The second frequency range, and a third frequency range from about 1690 MHz to about 3800 MHz, etc.).

As shown in Figures 1 through 3, the antenna 100 includes a mask or radome 108 (e.g., a flat plastic rectangular radome, etc.), and a support member or base plate 112 (e.g., a plastic backplane, etc.). . As shown in FIG. 3, the radome 108 and the base plate 112 cooperatively define an interior space in which a printed circuit board (PCB) 116 is positioned.

The radome 108 and the base plate 112 are configured to protect the printed circuit board 116 and conductive elements thereon (eg, the block 104, the ground plane 120, the radiator 124, the copper traces, etc.) for use Avoid damage caused by environmental conditions such as vibration or shock. The radome 108 and the bottom plate 112 can be formed from a wide variety of materials falling within the scope of the present disclosure, such as, for example, polymers, polyurethanes, plastic materials (eg, polycarbonate blends, PCs). /ABS (Polycarbonate-Acrylnitril-Butadien-Styrol-Copolymer) blends, etc.), reinforced glass plastic materials, synthetic resin materials, thermoplastic materials (such as Geloy® for exotic plastics) XP4034 resin, etc.), other dielectric materials, and the like.

The base plate 112 includes a threaded stud feature 128 (broadly speaking: a mounting feature or fixture) for mounting the antenna 100 to a roof (broadly speaking: a mounting surface). In this example, the base plate 112 integrally includes the threaded stud feature 128 such that the base plate 112 and the threaded stud feature have a unitary construction. Alternatively, the threaded stud feature 128 can be additionally attached (e.g., adhesively attached, mechanically secured, etc.) to the bottom plate 112.

As shown in FIG. 3, the threaded stud feature 128 generally exhibits a hollow shape such that a feed cable 132 (e.g., a coaxial cable, other transmission line, etc.) can be fed through the hollow interior of the threaded stud feature 128. . As shown in FIG. 6, the threaded stud feature 128 can have relatively small holes or openings 136 for the feed cable 132 to inhibit cable movement (eg, via a jamming or frictional engagement, etc.) Etc.) and reduce the risk of damage to the cable braid. Likewise, the feed cable 132 can be a coaxial cable that provides better PIM performance than a fixed connector that is less free to match the antenna 100.

By engaging the tabs 140 of the radome 108 to the openings or recesses 144 of the base plate 112, the radome 108 and the base plate 112 can be initially or temporarily coupled together. As shown in FIG. 6, the cleat 140 is along the edge of the radome 108, and as shown in FIG. 7, the recess 144 is along the edge of the bottom plate 112.

This radome 108 contains a heat stake 148 for final assembly. The heat stake 148 can be configured (e.g., sized, shaped, positioned, etc.) to be positioned within a corresponding hole or opening 152 in the printed circuit board 116 (Fig. 5). Hot melt column 148 Positioning within the opening 152 of the printed circuit board (as shown in Figures 3 and 4) is to align the printed circuit board 116 and assist in holding the position of the printed circuit board 116 relative to the bottom plate 112 and the radome 108. . This heat stake 148 can be configured to allow this antenna 100 to withstand drop and vibration testing without the need for mechanical fastening using screws. Similarly, the engagement of the tab 104 of the radome 108 with the recess 144 of the base plate 112 allows the antenna 100 to be tested prior to hot-melt implanting the radome 108 and the base plate 112 together. Alternatively, the radome 108 and the base plate 112 can be coupled together using other suitable means, such as mechanical fasteners, adhesives, and the like.

As shown in FIG. 2B, the radome 108 includes a protruding portion or at least one rib 156 that extends across a portion of the radome 108 such that the at least one rib 156 overlaps the ground plane 120. In this exemplary embodiment, the radome 108 includes three ribs 156 that are parallel to each other. This rib 156 provides an additional dielectric load to the antenna 100 to increase the electrical length of the ground plane 120.

As shown in FIG. 8, the rear side of the printed circuit board 116 includes a ground plane 120 and the block 104. This block 104 is coupled in a proximity manner to the radiator 124 (Fig. 9) along the opposite front side of the printed circuit board 116. The block 104 operatively increases the electrical length of the radiator to broaden the bandwidth of the antenna by extending or widening the frequency range downward. For example, increasing the block 104 can reduce the bottom of this frequency range from 698 MHz to 600 MHz, such that the antenna 100 has a larger bandwidth and has an acceptable omnidirectional radiation pattern. This block 104 may also be referred to herein as a suspended loaded block or a proximal block.

With continued reference to FIG. 8, the ground plane 120 includes an inclined surface 162 that It is configured to reduce the range of zero values and provide a better radiation pattern for the azimuthal plane. For example, the inclined surface 162 can include a linear or linear surface along an upper portion of the ground plane 120 between the two horizontal portions 164, 166 of the ground plane 120 and relative to the horizontal portions 164, 166 Present an angle. The creator of the present application recognizes the tilted surface 162 and the ratio between the length of the radiator and the length of the ground plane for the radiation pattern of the azimuthal plane (eg, the ground plane from the top along the map) The length from the left to the bottom of 10, etc.) is important. In this manner, in an exemplary embodiment, the angle of inclination of the inclined surface 162 relative to the horizontal may be from about 132 degrees to about 133 degrees (eg, 132 degrees, 132.5 degrees, 132.7 degrees, 132.9 degrees, 133 degrees, etc.).

The horizontal portion 166 of the ground plane extends or increases the size of this ground plane 120. This ground plane 120 also includes another portion 168 that extends or increases the size of this ground plane 120. Accordingly, the horizontal portion 166 and the other portion 168 of the ground plane electrically extend the ground plane 120.

This ground plane 120 includes a recess 170 for increasing the electrical path in the ground plane 120 that overlaps the surface of the radiator 124, thereby increasing the impedance. In this exemplary embodiment, the recess 170 is generally rectangular and generally perpendicular to the inclined surface 162 and extends inwardly from the inclined surface 162. Alternatively, the recess 170 can be configured differently, such as using a different shape, at a different location, using a different orientation relative to the inclined surface 162, and the like.

This ground plane 120 also includes a plurality of grooves 172 (broadly speaking: openings) along opposite sides of the feed ground point 174 (Figs. 4 and 8). As shown in Figures 4 and 8, the braid of this feed cable 132 can be soldered to the solder pads exposed on this ground plane. This groove 172 can be configured to be particularly useful for high frequency bandwidth. Additionally, this groove 172 can also be configured to reduce the surface for soldering to reduce the risk of high PIM levels. In this exemplary embodiment, the grooves 172 are generally rectangular and aligned or parallel to each other. Alternatively, the grooves 172 can be configured differently, such as using a different shape, at a different location, using a different orientation relative to each other, and the like.

Generally, such recesses 170, 172 are a missing of the conductive material in this ground plane 120. For example, the ground plane 120 may be initially formed with the recesses 170, 172, or the recesses 170, 172 may be formed by removing conductive material from the ground plane 120, such as etching, cutting, Stamping and so on. In still other embodiments, the recesses 170, 172 may be formed from a non-conductive or dielectric material that is incorporated into the ground plane 120, such as by printing or the like.

As shown in FIG. 9, the front side of the printed circuit board 116 includes the radiator 124. The radiator 124 includes a primary or first radiating element 176 that is configured to operatively drive the radiator 124 to resonate at low frequencies as low as 698 MHz. This radiator 124 further includes two high frequency (or second and third) radiating elements or arms 178 and 180. This high frequency radiating element or arm 178 is configured to operatively drive the radiator 124 to resonate from a high frequency of 1350 MHz to 1710 MHz. Another high frequency radiating element or arm 180 is configured to operatively drive the radiator 124 to resonate from 1710 MHz to 3800 MHz and the high frequencies thereon. When a shorter length can provide a higher bandwidth but sacrifices the radiation pattern, the high frequency radiating elements 178 and/or 180 can have a length sufficient to maintain or improve the omnidirectional pattern. The creators of the present application also recognize that for the high frequency matching, the gaps 181, 183 between the bottom radiator arms or portions of the radiator 124 to the ground plane 120 are important.

Figure 9 also shows a microstrip line 182 between the radiator 124 and a feed point 184 for the central core of the feed cable 132 to be soldered. The width of this microstrip line 182 can be used to match the impedance of this antenna 100. Therefore, the microstrip line 182 is not necessarily designed to have a characteristic impedance of 50 ohms.

As shown in FIG. 4, this feed cable 132 is electrically coupled to a feed ground point 174 along the rear side of the printed circuit board 116. This feed cable 132 is also electrically coupled to the radiator 124 on the opposite front side of the printed circuit board 116. In this exemplary embodiment, the printed circuit board 116 includes a hole 186 (Fig. 5) through which the central core of the feed cable 132 is electrically coupled to the feed point 184 (Fig. 8). This feed point 184 is electrically coupled to the electrical transmission line of this microstrip line 182, which is then electrically coupled to this radiator 124.

In this exemplary embodiment, the block 104, the ground plane 120, the radiator 124, and the microstrip line 182 include conductive traces (e.g., copper, etc.) along the printed circuit board 116. Alternatively, the block 104, the ground plane 120, the radiator 124, and/or the microstrip line 182 may comprise other conductive elements than copper traces on a printed circuit board, such as via stamped parts. An element manufactured by a plastic plating method, an element constructed by cutting, stamping, etching to be formed from a sheet material, or the like.

This printed circuit board 116 may include a circuit board manufactured from a glass-reinforced resin laminate or the like containing a flame-retardant (FR4). Additionally or alternatively, the antenna 100 can comprise a flexible or rigid substrate, a plastic carrier, an insulator, a flexible circuit board, a flexible film, and the like.

10, 11 and 12 provide an exemplary dimension (in millimeters) of this printed circuit board 116. As shown, the printed circuit board 116 can have a height of approximately 170 millimeters. A width of about 100 mm, and a thickness of about 0.8 mm. The dimensions in this paragraph merely provide exemplary purposes in accordance with the exemplary embodiments, in that alternative embodiments may be variously configured, such as smaller or larger, and the like.

FIG. 13 is a diagram illustrating another printed circuit board 216 that can be used with the antenna 100 shown in FIGS. 1 through 3 in accordance with another exemplary embodiment. This printed circuit board 216 can be similar or substantially identical to the printed circuit board 116 described above and illustrated in Figures 8 and 9. For example, the printed circuit board 216 also includes a radiator 224 and a ground plane 220 along its opposite front and rear sides. However, in this exemplary embodiment, the printed circuit board 216 does not include a block 104 along its rear side. Moreover, the printed circuit board 216 includes a primary or first radiating element 276 having a shape that is different from the corresponding primary or first radiating element 176 in the radiator 124.

As shown in FIG. 13, this ground plane 220 includes an inclined surface 262, a horizontal portion 264, and grooves 270, 272 that are constructed and operated similar to the corresponding inclined surface 162, horizontal portion 164, and groove. 170, 172.

For example, this inclined surface 262 can be configured to reduce the range of zero values and provide a better radiation pattern for the azimuthal plane. By way of example, in an exemplary embodiment, the angle of inclination of the inclined surface 262 relative to the horizontal may be from about 132 degrees to about 133 degrees (eg, 132 degrees, 132.5 degrees, 132.7 degrees, 132.9 degrees, 133 degrees, etc.).

This horizontal portion 264 extends or increases the size of this ground plane 220 and electrically extends this ground plane 220. This recess 270 can increase the electrical path in the ground plane 220 that overlaps the surface of the radiator 224, thereby increasing the impedance. The grooves 272 (in a broad sense: openings) along the opposite sides of the feed ground point can improve the bandwidth especially for high frequencies and reduce Surfaces used for soldering to reduce the risk of high PIM levels.

This radiator 224 includes a primary or first radiating element 276 and two high frequency (or second and third) radiating elements or arms 278 and 280. This primary or first radiating element 276 can be configured to operatively drive the radiator 224 to resonate at low frequencies, such as as low as about 698 MHz, and the like. The high frequency radiating element or arm 278 can be configured to operatively drive the radiator 224 to resonate at a first high frequency, such as from about 1350 MHz to about 1525 MHz, and the like. Another high frequency radiating element or arm 280 can be configured to operatively drive the radiator 224 to resonate at a second high frequency above the first high frequency, such as from about 1690 MHz to about 3800 MHz, and the like.

Figure 13 is also showing the electrical transmission of a microstrip line 282. This microstrip line 282 extends between the radiator 224 and a feed point 284. This feed point 284 can be configured for central core welding of the cable 232.

This antenna 100 can have an ultra-low profile design (e.g., a radome having a height or thickness of about 7.6 millimeters or less, etc.). For example, the dimensions of the radome 108 can be 180.3 mm by 117.2 mm by 7.6 mm. The antenna 100 can be used as a top-mounted bevel-type network antenna in a building. This antenna 100 can be configured to be aesthetically pleasing, unobtrusive, and/or have an appearance for blending or matching the color with the color of the roof or other mounting surface for the antenna. For example, the radome 108 of the antenna 100 can be white or otherwise colored to blend or match the color of the roof (eg, ceiling tiles or panels, etc.) to which the antenna 100 can be mounted. Again, the radome 108 can be relatively flat such that the radome 108 will be flush with the roof, unobtrusive, and will not significantly protrude outwardly from the roof after the antenna 100 is mounted to the roof. In this paragraph (and in this specification and schema) Dimensions in other places merely provide exemplary purposes in accordance with the exemplary embodiments, in that alternative embodiments may be variously configured, such as smaller or larger, and the like.

15B through 81 are results of providing measurements for a prototype of the antenna 100 as shown in FIGS. 1 through 3 having a printed circuit board 116 as shown in FIGS. 10 through 12 having This block 104. 15A and FIG. 84 to FIG. 137 are results of providing measurement for a prototype of the antenna 100 as shown in FIGS. 1 to 3 having a printed circuit board as shown in FIGS. 14A and 14B. 216. The results of such analysis are for illustrative purposes only and are not limiting, and other exemplary embodiments may be variously configured and/or may have different performance.

More specifically, FIG. 15A is an exemplary line graph of voltage standing wave ratio (VSWR) with respect to frequency in megahertz (MHz), which is for having as shown in FIGS. 14A and 14B. A prototype of the printed circuit board 216 of the antenna 100 as shown in FIGS. 1 through 3 does not include the block 104. In general, Figure 15A is a diagram showing a prototype antenna that does not have this block operatively having a good voltage standing wave ratio (VSWR) of less than 1.8 to 1 for a first frequency range from about 698 MHz to about 960 MHz. The frequency within, and for a frequency in a second frequency range from about 1690 MHz to about 3800 MHz.

Figure 15B is an exemplary line graph of voltage standing wave ratio (VSWR) versus frequency in megahertz (MHz) for a printed circuit board 116 as shown in Figures 10-12. A prototype of the antenna 100 as shown in FIGS. 1 through 3 includes the block 104. In general, Figure 15B is a diagram showing that a prototype antenna having such a block has a good voltage standing wave ratio (VSWR) of less than 1.8 to 1 operationally for a wide frequency range from about 600 MHz to about 3800 MHz. frequency. A comparison of Figure 15A and Figure 15B It is also shown that the increase of this block 04 can extend the frequency down to 600 MHz.

16 to 81 are diagrams illustrating radiation field types (azimuth plane, Phi 0 degree plane, and Phi 90 degree plane) at various frequencies, respectively, for the measurement as shown in FIGS. 14A and 14B. The prototype of the antenna 100 of the printed circuit board 216 as shown in FIGS. 1 to 3 does not include the block 104, and the frequencies include 698 MHz, 746 MHz, 824 MHz, 894 MHz, 850 MHz, 960 MHz, 1350 MHz, 1448 MHz. 1427MHz, 1525MHz, 1710MHz, 1850MHz, 1930MHz, 2130MHz, 2170MHz, 2310MHz, 2412MHz, 2506.5MHz, 2600MHz, 2700MHz, 3300MHz, and 3800MHz. In general, Figures 16 through 81 are diagrams showing a reasonable omnidirectional radiation pattern and good efficiency of a prototype antenna without the block, which falls within a first frequency range from about 698 MHz to about 960 MHz. Various frequencies in a second frequency range from about 1350 MHz to about 1525 MHz, and a third frequency range from about 1710 MHz to about 3800 MHz.

82 and 83 are exemplary line graphs of passive intermodulation level (PIM) relative carrier (dBc) in decibels in frequency in megahertz (MHz), which is The prototype of the antenna 100 of the printed circuit board 216 shown in FIGS. 14A and 14B as shown in FIGS. 1 through 3 does not include this block 104. Figure 82 and Figure 83 show PIM (IM3) performance at the respective transmission (Tx) frequencies of 728 MHz to 757 MHz and 1930 MHz to 1990 MHz for two transmitted carriers (20 watts each). As shown, a prototype antenna without a block has a good low PIM directional energy (eg, better or less than -150 dBc, etc.), a low frequency peak of -158.9 dBc at 776 MHz, and -153.5 at 1899 MHz. A high frequency peak of dBc.

Figures 84 to 137 are diagrams illustrating radiation patterns at various frequencies (square The bit plane, the Phi 0 degree plane, and the Phi 90 degree plane), this measurement is for the antenna 100 as shown in FIGS. 1 to 3 having the printed circuit board 116 as shown in FIGS. 10 to 12. a prototype comprising the block 104, and the frequencies include 600 MHz, 645 MHz, 698 MHz, 824 MHz, 850 MHz, 960 MHz, 1350 MHz, 1500 MHz, 1525 MHz, 1680 MHz, 1850 MHz, 1990 MHz, 2170 MHz, 2310 MHz, 2510 MHz, 2700 MHz, 3300 MHz, and 3800MHz. In general, Figures 84 through 137 are diagrams showing a reasonable omnidirectional radiation pattern and good efficiency of a prototype antenna having such a block, which are in a wide frequency range falling from about 600 MHz to about 3800 MHz. frequency.

Figure 138 and Figure 139 are exemplary line graphs of passive intermodulation variable level (PIM) relative carrier (dBc) in decibels versus frequency in megahertz (MHz), which is The prototype of the antenna 100 as shown in FIGS. 1 through 3 of the printed circuit board 116 shown in FIGS. 10 through 12 includes the block 104. Figures 138 and 139 show PIM (IM3) performance at respective transmission (Tx) frequencies of 728 MHz to 757 MHz and 1930 MHz to 1990 MHz for two transmitted carriers (20 watts each). As shown, a prototype antenna with a block has good low PIM performance (eg, preferably or less than -150 dBc, etc.), has a low frequency peak of -160.7 dBc at 776 MHz, and has -156.5 dBc at 1901 MHz. A high frequency peak.

Figure 140 is another exemplary embodiment of an omnidirectional SISO antenna 300 that illustrates one or more aspects of the present disclosure. As shown, this antenna 300 includes a radiator 324 along a printed circuit board 316, and an electrically conductive (e.g., aluminum or the like) tape or foil 320 (broadly speaking: a ground plane). This conductive tape or foil 320 (e.g., aluminum foil, etc.) is at least a portion defining the ground plane of the antenna 300.

In this exemplary embodiment, the conductive tape or foil 320 is shown to be coupled to one of the grounds of the radiator 324 via an approximate coupling and is thereby electrically insulated by the mask of the printed circuit board 316 itself. As shown in FIG. 140, a portion 388 of this conductive tape 320 is disposed on a portion 322 of the printed circuit board 316 and overlaps the portion 322. Portion 322 of this printed circuit board 316 that overlaps portion 388 of this conductive tape or foil 320 contains at least a portion of the ground (e.g., copper traces, etc.) for this radiator 324. Portion 388 of the conductive tape 320 overlaps the portion 322 of the printed circuit board 316 to provide a proximal coupling between the conductive tape or foil 320 and the ground 322 of the radiator 324.

This radiator 324 can be similar or identical to the radiator 124 shown in Figures 5 and 9. Accordingly, the radiator 324 can likewise comprise a primary or first radiating element 376, as well as two high frequency radiating elements or arms 378 and 380. Alternatively, the radiator 324 can have a different configuration, such as similar or identical to the radiator 224 shown in FIG.

With continued reference to FIG. 140, the conductive tape or foil 320 includes an inclined surface 362 and stub or horizontal portions 364, 368 that may be constructed and operated similar to the corresponding inclined surface 162 and horizontal portion 164 of the ground plane 120. 168. For example, such horizontal portions 364, 368 extend or increase the size of the conductive tape or foil 320 and electrically extend the conductive tape or foil 320. This inclined surface 362 can be configured to reduce the range of zero values and provide a better radiation pattern for the azimuthal plane.

Portion 322 of this printed circuit board 316 that overlaps this conductive tape or foil 320 includes grooves 370 and 372. The construction and operation of such grooves 370 and 372 can be similar to grooves 170 and 172 of this ground plane 120.

The printed circuit board 316 does not extend completely over the conductive tape or foil 320. Above, it requires less printed circuit board material. As shown in FIG. 140, the printed circuit board 316 extends across or overlaps only a portion 388 of the conductive tape or foil 320. In this exemplary embodiment, the printed circuit board 316 is approximately half the size of the printed circuit board 116 shown in FIG. The cost of this antenna is reduced by using less of a relatively expensive printed circuit board material (e.g., a flame-retardant-containing glass reinforced resin laminate, etc.).

This antenna 300 includes a block 304 that is similar or identical to the block 104 shown in Figures 4 and 8 and described above. This block 304 can be coupled in close proximity to the radiator 324 along the opposite front side of the printed circuit board 316. This block 304 can operatively increase the electrical length of the radiator 324 to broaden the bandwidth of the antenna by extending or widening the frequency range downward. In other embodiments, the antenna 300 does not include any blocks on the back side of the printed circuit board 316.

Figure 140 is an electrical transmission that also shows a microstrip line 382. This microstrip line 382 extends between the radiator 324 and a feed point 384. This feed point 284 can allow the central core of one coaxial feed cable 390 to be soldered. For example, the internal conductors of this coaxial feed cable 390 can be electrically connected (eg, via soldering, etc.) to the radiator 324. The outer cable braid of this coaxial feed cable 390 can be electrically connected (e.g., via soldering, etc.) to a portion 322 of the printed circuit board 316 that overlaps the conductive tape or foil 320 and includes at least a portion of this ground.

This antenna 300 may also include a base plate and radome that is similar or identical to the base plate 112 and radome 108 shown in FIG. 1 and described above.

This antenna 300 can be configured for broadband operation or multi-frequency operation. For example: this antenna 300 can be configured to operate over a wide frequency range, such as from approximately 600 MHz To about 3800MHz and so on. Or, for example, the antenna 200 can be configured to operate in a plurality of frequency ranges, such as a first frequency range from about 698 MHz to about 960 MHz, a second frequency range from about 1350 MHz to about 1525 MHz, and A third frequency range from about 1690 MHz to about 3800 MHz, and the like.

This antenna 300 can have an ultra-low profile design (e.g., a radome having a height or thickness of about 7.6 millimeters or less, etc.). For example: the dimensions of this radome can be 180.3 mm by 117.2 mm by 7.6 mm. The antenna 300 can be used as a top-mounted bevel-type network antenna in a building. This antenna 300 can be configured to be aesthetically pleasing, unobtrusive, and/or have an appearance for blending or matching the color with the color of the roof or other mounting surface for the antenna. For example, the radome of this antenna 300 can be white or otherwise colored to blend or match the color of the roof (eg, ceiling tiles or panels, etc.) to which the antenna 300 can be mounted. Again, the radome can be relatively flat such that the radome will be flush with the roof, unobtrusive, and will not significantly protrude outwardly from the roof after the antenna 300 is mounted to the roof. The dimensions in this paragraph (and elsewhere in this specification and drawings) merely provide exemplary purposes in accordance with the exemplary embodiments, in which alternative embodiments may be variously configured, such as smaller or larger and many more.

141 is an exemplary dimension (in millimeters) and angle (in degrees) provided for a conductive tape or foil 320 as shown in FIG. 140, which is set in accordance with an exemplary embodiment and serves only as For illustrative purposes. In this exemplary embodiment shown in FIG. 141, the height is 100 mm, and the inclined angle of the inclined surface with respect to the horizontal is 133 degrees. Alternative embodiments may be configured differently, such as smaller, larger, have different shapes, and the like.

Figure 142 is the voltage standing wave ratio relative to the frequency in megahertz (MHz). An exemplary line graph of (VSWR) for a prototype of an antenna 300 including a printed circuit board 316, a radiator 324, and an aluminum conductive tape or foil 320 as shown in FIG. The dimensions have dimensions similar to those described herein. In general, Figure 142 is an achievable bandwidth showing an antenna comprising a printed circuit board 316, a radiator 324, and an aluminum conductive tape or foil 320. Figure 142 also shows that an antenna comprising printed circuit board 316, radiator 324, and aluminum conductive tape or foil 320 operatively has a good voltage standing wave ratio (VSWR) of less than 1.8 to 1, which is for approximately A frequency in a frequency range from 608 MHz to about 960 MHz, and a frequency from about 1520 MHz to about 2700 MHz. As shown in FIG. 142, the voltage standing wave ratio is 1.72 at 608 MHz, 1.21 at 698 MHz, 1.1 at 824 MHz, 1.21 at 960 MHz, 1.58 at 1520 MHz, and 1.45 at 1710 MHz. It is 1.11 at 2170 MHz and 1.16 at 2700 MHz. The results of such voltage standing wave ratios are merely for illustrative purposes and are not limiting, while other exemplary embodiments may be configured differently and/or may have different performances.

143 and 144 are another exemplary embodiment of an omnidirectional SISO antenna 400 that illustrates one or more aspects of the present disclosure. As shown in FIG. 143, this antenna 400 includes a dielectric spacer 492 (eg, a plastic gasket or the like) positioned between the support member or base plate 412 and the rear side of the printed circuit board 416. This dielectric spacer 492 is typically disposed adjacent a second opening or aperture 494 of the threaded stub 428 of the bottom plate 412.

The antenna 400 also includes a feed cable 432 (e.g., a coaxial cable, other transmission line, etc.) that is fed through a first opening and through the hollow interior of the threaded stud feature 428, and The second opening leaves to a feed ground point. The first opening of the threaded stud feature 428 can be relatively small to inhibit cable movement (e.g., via a disturbing or frictional engagement, etc.) and reduce the risk of damage to the cable braid. Likewise, the feed cable 432 can be a coaxial cable that provides better PIM performance than a fixed connector that is less free to match the antenna 400.

144 is a view showing that the printed circuit board 416 and the dielectric spacer 492 are positioned within an interior enclosed space that is cooperatively defined between the bottom plate 412 and a radome 408. In the absence of this dielectric spacer 492, the area indicated by the elliptical shape 496 near the aperture 494 of the threaded stub 428 can be affected by deformation or deflection during a pull test. This pull test is indicated by the down arrow in Figure 144.

The dielectric spacer 492 is configured to assist in reducing or eliminating deformation or deflection of the printed circuit board 416 near or around the aperture 494, which may occur due to substrate material of the printed circuit board 416 (eg, Softness or flexibility of type and/or thickness, etc.). The deformation or deflection of the printed circuit board 416 can increase the PIM level and change the voltage standing wave ratio of the antenna 400. The dielectric spacer 429 is to assist in making the region 496 near the relatively short stud 494 more tough and less susceptible to deformation or deflection without damaging the printed circuit board and increasing the PIM position. quasi. Accordingly, the dielectric spacer 429 can thus make the printed circuit board tougher, reduce distortion or deflection due to the pull test, and assist in maintaining an acceptable PIM level and voltage standing wave of the antenna 400. ratio.

This printed circuit board 416 can be similar or substantially identical to one of the printed circuit boards described herein, such as the printed circuit board 116 shown in Figures 8 and 9, and the printing shown in Figures 10 through 12. A circuit board, a printed circuit board shown in FIG. 140, and the like. This bottom plate 412 and radome 408 may be similar or substantially identical to one of the base plates and radomes described herein, such as base plate 112 and radome 108 shown in Figures 1-4, 6, and 7, and the like. This radome 408 can be similar or substantially identical to one of the radomes described herein, such as the radome 108 shown in Figures 1-4. Any of the plurality of antennas described herein may also include a dielectric spacer 492 as shown in FIGS. 143 and 144.

The illustrative embodiments are provided so that this description will be more comprehensive and will be fully conveyed by those skilled in the art. Numerous specific details are set forth, such as examples of specific components, devices, and methods, to provide a comprehensive understanding of the embodiments of the present disclosure. It will be apparent to those skilled in the art <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; In some exemplary embodiments, well-known processes, well-known device structures, and well-known techniques are not described in detail. In addition, the advantages and modifications that may be achieved by one or more exemplary embodiments of the present disclosure are for illustrative purposes only and are not intended to limit the scope of the present disclosure, as the exemplary embodiments described herein. It is possible to provide all of the advantages and improvements mentioned above or to provide any of the advantages and improvements mentioned above, and still fall within the scope of this description.

The specific dimensions, specific materials, and/or specific shapes described herein are merely examples in nature and are not intended to limit the scope of the disclosure. The specific numerical values of the given parameters and the specific numerical ranges recited herein do not exclude other values and other numerical ranges that may be used in one or more of the examples recited herein. Furthermore, it is envisioned that any two specific values of the specific parameters described herein may define an end point that applies to a range of values for that given parameter (that is, for one given in this document) Parameterized The description of a first value and a second value can be interpreted to mean that any value between the first value and the second value can be applied to the given parameter as well. For example, if parameter X is exemplified herein as having a value of A and is also illustrated as having a value of Z, it is envisioned that parameter X may have a range of values from about A to about Z. Similarly, it is envisioned that two or more ranges of values for a parameter (whether or not such ranges are nested, overlapping or different) contain such claimed that the end points of the recited range are claimed. A combination of all possible ranges of values. For example, if the parameter X is exemplified herein as having a value ranging from 1 to 10, or 2 to 9, or 3 to 8, it is also envisioned that the parameter X may have other numerical ranges, Contains: 1 to 9, 1 to 8, 1 to 3, 1 to 2, 2 to 10, 2 to 8, 2 to 3, 3 to 10, and 3 to 9.

The terminology used herein is for the purpose of describing the particular exemplary embodiments, As used herein, the singular forms """ The terms "including", "comprising" and "having" are intended to be inclusive, and, therefore, the meaning of the characteristic figures, things, steps, operations, components, and/or components are explicitly recited, but one or more The existence of other features, things, steps, operations, components, components, and/or groups thereof does not even exclude one or more other features, objects, steps, operations, components, components, and/or The presence or addition of a group. The method steps, processes, and operations described herein are not to be construed as being necessarily in a particular order discussed or illustrated herein. It should also be understood that additional or alternative steps can be applied.

When a component or layer is referred to as "located," "connected to," "connected to," or "coupled to" another element or layer, it may be located directly, Connected to, connected to, or coupled to this other element or another layer, or an intermediate element or intermediate layer may be present. Conversely, when an element is referred to as being "directly," "directly connected," "directly connected to," or "directly coupled to" another element or another layer, Any intermediate component or intermediate layer. Other terms used to describe the relationship between components should also be interpreted in the same way (for example: "between" and "directly between" and "adjacent" relative to "direct" Neighboring, etc.) As used herein, the term "and/or" includes any and all combinations of one or more of the associated list items.

The term "about" when applied to a numerical value indicates that the calculation or measurement allows for some imprecision in value (somewhat close to an exact value; approximately or reasonably close to this value; almost). If, for some reason, the inaccuracy provided by "about" is not otherwise understood in the ordinary sense of the art, the term "about" as used herein means that it can at least be due to general measurement methods or Use the changes caused by this parameter. For example, "general", "about" and "substantial" may be used in this context to mean that they are within manufacturing tolerances.

Although the first, second, third, etc. may be used herein to describe various elements, components, regions, layers, and/or sections, such elements, components, regions, layers, and/or sections are not It should be limited to these terms. The terms may be used to distinguish one element, component, region, layer or layer to another region, layer or segment. Terms such as "first," "second," and other values are used in this document unless the context clearly indicates otherwise. Thus, a first element, component, region, layer or section may also be referred to as a second element, component, region, layer or section without departing from the teachings of the exemplary embodiments.

For the convenience of narration, you can use such things as "internal", "external", Spatial terms and similar terms used in "lower", "lower", "lower", "above" and "upper" to describe one element or feature and other component(s) as illustrated in the drawings. Or (multiple) characteristic relationships. Spatially related terms may also be intended to encompass different orientations of the device in use or operation, in addition to the orientation depicted in the drawings. For example, elements that are described as "below" or "beneath" other elements or features in the <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; Thus, the exemplifying term "lower" can encompass both both an orientation and an orientation. This device may be otherwise oriented (rotated 90 degrees or at other orientations) and such spatial relationship descriptors are hereby interpreted accordingly.

The foregoing description of the embodiments has been provided for purposes of illustration and description. There is no intention to exhaust or limit the contents of this document. Even if not specifically shown or described herein, the individual elements, contemplated or recited uses, or features of a particular embodiment are generally not limited to this particular embodiment, and may be used interchangeably and can be used in a selected implementation, as appropriate. In the example. The individual elements, contemplated or recited uses, or characteristics described above can also be varied in many ways. Such variations are not to be regarded as a departure from the description, and all such modifications are intended to be included within the scope of the present disclosure.

300‧‧‧ (omnidirectional SISO) antenna

304‧‧‧Blocks

316‧‧‧Printed circuit board

320‧‧‧Conductive tape/foil

322‧‧‧Part/ground

324‧‧‧radiator

362‧‧‧Sloping surface

364, 368‧‧‧ horizontal section

370, 372‧‧‧ grooves

376‧‧‧main or first radiating element

378, 380‧‧‧ High-frequency radiating elements/arms

382‧‧‧Microstrip line

384‧‧‧ Feeding points

Section 388‧‧‧

390‧‧‧Coaxial Feed Cable

Claims (26)

An antenna comprising: a radiator; and a ground plane comprising an inclined surface along an edge portion of the ground plane or for defining the edge portion, whereby the tilt The surface is configured to be operative to reduce a range of zero values in the azimuthal plane, thereby allowing the antenna to have a more omnidirectional radiation pattern in the azimuthal plane. The antenna of claim 1, wherein the antenna further comprises a substrate having opposite front and rear sides, and wherein: the radiator is along the front side of the substrate; The ground plane is along the back side of the substrate. The antenna of claim 2, the antenna further comprising a patch along the rear side of the substrate, the block being separated from the ground plane, The block is coupled in close proximity to the radiator along the front side of the substrate to increase the electrical length of the radiator and thereby widen the antenna by extending the frequency range downwardly bandwidth. The antenna of claim 2, wherein the antenna comprises a horizontal planar asymmetric dipole antenna, the horizontal planar asymmetric dipole antenna along a corresponding one of the substrates The front side and the rear side have a first asymmetric arm and a second asymmetric arm; the first asymmetric arm defines or contains the radiator; and the second asymmetric arm defines or contains The ground plane. The antenna of claim 2, wherein the microstrip electrical transmission line is along the front side of the substrate and extends over the radiator and the feed point. The substrate includes a printed circuit board; the radiator includes conductive traces along the front side of the printed circuit board; and the ground plane includes along the back side of the printed circuit board Conductive tape or foil, and/or conductive traces. The antenna of claim 1, wherein the ground plane comprises: a groove from the ground plane defined by the inclined surface An edge portion extending inwardly, the groove being configured to operatively increase an electrical path of the surface of the ground plane that overlaps the radiator, thereby increasing impedance for impedance matching; and/or at least one groove The at least one groove is adjacent the feed ground point and is configured to operate to improve bandwidth, and/or to reduce surface for soldering, thereby reducing the risk of high passive intermodulation levels occurring . The antenna of claim 1, wherein the antenna comprises: a rectangular recess, the rectangular recess being substantially perpendicular to the ground plane by the inclined surface The edge portion is defined and extends inwardly from the edge portion; and/or a pair of rectangular grooves along opposite sides of the feed ground point. The antenna of claim 1, wherein the ground plane comprises: a first portion, the first portion being adjacent the end portion of the inclined surface and extending outwardly relative to the ground plane to electrically extend the ground plane; and/or the second portion, the second portion A portion is spaced apart from the inclined surface and extends outwardly relative to the ground plane to electrically extend the ground plane. The antenna of claim 1, wherein the antenna is a single-input single-output (SISO) and a top-mounted cellular antenna in the building; and/ Or the antenna has an ultra-low profile with a radome having a height of approximately 7.6 mm. The antenna of claim 1, wherein the radiator comprises: a first radiating element, the first radiating element being configured to operatively drive the radiator to Resonating at a low frequency; a second radiating element configured to operatively drive the radiator to resonate at a first high frequency; and a third radiating element configured to operate The radiator is driven up to resonate at a second high frequency higher than the first high frequency. The antenna of claim 1 or 3, wherein the antenna further comprises: a bottom plate including mounting features for mounting the antenna to a mounting surface; a radome, the radome being Coupled to the backplane; wherein the radiator and the ground plane are positioned within an interior space, the interior spaces being cooperatively defined between the radome and the backplane; and wherein the mounting features Containing a hollow interior space to allow the coaxial feed cable to pass through a hollow interior space is fed to the feed ground point; and wherein: the radome includes at least one rib or protrusion at a predetermined location along itself, the at least one rib or protrusion providing additional to the antenna a dielectric load thereby increasing the electrical length of the ground plane; and/or the mounting feature includes the coaxial feed cable for entering a first opening of the hollow interior space, the first opening being sized Designed to inhibit cable movement, thereby reducing the risk of damage to the cable braid of the coaxial feed cable; and/or the antenna further includes a substrate and a dielectric spacer having opposing front and rear sides a side, along the front side and the rear side, the radiator and the ground plane are respectively positioned, and the dielectric spacer is between the bottom plate and the rear side of the substrate The dielectric spacer is disposed generally around the second opening of the mounting feature and is configured to assist in reducing deformation or deflection of the substrate adjacent the second opening. The antenna of claim 1, wherein the antenna is configured for broadband operation such that the antenna operates across a wide frequency range; or the antenna It is configured for multi-frequency operation such that the antenna is operative in at least a first frequency range and a second frequency range different from the first frequency range. The antenna of claim 1, wherein the antenna is configured to operate operatively in a frequency range from about 600 MHz to about 3800 MHz, and from about 600 MHz to about 3800 MHz. At a frequency within the frequency range, the antenna is omnidirectional in the azimuthal plane; or The antenna is configured to operate operatively in a first frequency range from about 698 MHz to about 960 MHz, a second frequency range from about 1350 MHz to about 1525 MHz, and a third frequency range from about 1690 MHz to about 3800 MHz, and At a frequency within the first frequency range, the second frequency range, and the third frequency range, the antenna is omnidirectional in the azimuthal plane. The antenna of claim 1, wherein the antenna further comprises a conductive tape or foil for defining at least a portion of the ground plane. The antenna of claim 14, wherein: the antenna further comprises a substrate having opposite front and rear sides; the radiator along the front side of the substrate; and the radiation A portion of the ground along the back side of the substrate overlaps a portion of the conductive tape or foil, thereby providing a proximity between the conductive tape or foil and the ground of the radiator Coupling. The antenna of claim 15, wherein the conductive tape or foil is electrically insulated by a mask of the substrate. The antenna of claim 15 wherein: said substrate covers only a portion of said conductive tape or foil; and/or said conductive tape or foil comprises said to define said ground plane The inclined surface of the edge portion; and/or the conductive tape or foil does not include any grooves; and/or the conductive tape or foil comprises at least one portion opposite to the conductive tape Or extending outwardly from the ground plane defined by the foil, thereby electrically extending The ground plane. The antenna of claim 1, wherein the antenna is configured to have a voltage standing wave ratio of less than 1.8 to 1 in a frequency range from about 600 MHz to about 3800 MHz ( VSWR) and/or operation with passive intermodulation (IM3) with a relative carrier (dBc) less than -150 dB. The antenna of claim 1, wherein the antenna is configured to have a good voltage of less than 1.8 to 1 in a first frequency range from about 698 MHz to about 960 MHz. Standing wave ratio (VSWR) and/or passive intermodulation (IM3) with a relative carrier (dBc) less than -150 decibels; the antenna being configured to be in a second frequency range from about 1350 MHz to about 1525 MHz, Operating at a voltage standing wave ratio (VSWR) of less than 2 to 1 and/or passive intermodulation (IM3) with a relative carrier (dBc) of less than -150 decibels; and the antenna is configured to be from approximately 1690 MHz to approximately In the third frequency range of 3800 MHz, operation is performed with a voltage standing wave ratio (VSWR) of less than 1.8 to 1 and/or a passive intermodulation (IM3) of less than -150 dB with respect to a carrier (dBc). An antenna comprising: a substrate; a radiator along the substrate; and a conductive tape or foil defining at least a portion of a ground plane, the conductive tape or foil The patch is coupled to the ground of the radiator via a proximity coupling and is electrically insulated by a mask of the substrate. The antenna of claim 20, wherein the conductive tape or foil comprises An inclined surface along an edge portion of the ground plane or to define the edge portion, whereby the inclined surface is configured to be operative to reduce a range of zero values in the azimuth plane, thereby allowing The antenna has a more omnidirectional radiation pattern in the azimuthal plane. An antenna according to claim 20, wherein: said substrate comprises opposite front and rear sides; said radiator is along said front side of said substrate; said radiator A portion of the conductive tape or foil is overlapped along a portion of the ground of the back side of the substrate, thereby providing a close coupling between the conductive tape or foil and the ground of the radiator And the antenna further includes a block along the rear side of the substrate, the block being spaced apart from the ground plane, whereby the block is coupled in a proximate manner along The radiator on the front side of the substrate is used to increase the electrical length of the radiator and thereby widen the antenna bandwidth by extending the frequency range downward. The antenna of claim 20, wherein the substrate covers only a portion of the conductive tape or foil; and/or the conductive tape or foil comprises at least one portion, At least one portion extends outwardly relative to the ground plane defined by the conductive tape or foil, thereby electrically extending the ground plane; and/or wherein the radiator comprises: a first radiating element, The first radiating element is configured to operatively drive the radiator to resonate at a low frequency; the second radiating element is configured to operatively drive the radiation Resonating at a first high frequency; and a third radiating element configured to operatively drive the radiator to resonate at a second high frequency above the first high frequency. The antenna of claim 20 or 21, wherein the antenna further comprises: a bottom plate including mounting features for mounting the antenna to a mounting surface; a radome, the radome being Coupled to the base plate; wherein the substrate, the radiator, and the conductive tape or foil are positioned within an interior space that is cooperatively defined between the radome and the backplane And wherein the mounting feature comprises a hollow interior space to allow a coaxial feed cable to be fed to the feed ground point through the hollow interior space; and wherein: the radome comprises at least one of a predetermined position along itself a rib or protruding portion, the at least one rib or protruding portion providing an additional dielectric load to the antenna, thereby increasing an electrical length of the ground plane; and/or the mounting feature comprising the coaxial feed cable a wire is used to enter a first opening of the hollow interior space, the first opening being sized to inhibit cable movement, thereby reducing the coaxial feed cable Risk of damage to the cable braid; and/or the antenna further includes a dielectric spacer between the bottom plate and the substrate whereby the dielectric spacer is disposed substantially at the mounting feature Surrounding the second opening and configured to assist in reducing deformation or deflection of the substrate adjacent the second opening. For example, the antenna described in claim 20 or 21, wherein: The antenna is a single-input single-output (SISO) and a top-mounted cellular network antenna in the building; and/or the antenna has an ultra-low profile with a radome having a height of approximately 7.6 mm. The antenna of claim 20, wherein the antenna is configured to operate operatively in a frequency range from about 600 MHz to about 3800 MHz, and in a frequency range from about 600 MHz to about 3800 MHz. At the frequency, the antenna is omnidirectional in the azimuth plane; or the antenna is configured to operate operatively at a first frequency range from about 698 MHz to about 960 MHz, from about 1350 MHz to about 1525 MHz a frequency range, and a third frequency range from about 1690 MHz to about 3800 MHz, and at frequencies in the first frequency range, the second frequency range, and the third frequency range, the antenna is in the The azimuthal plane is an omnidirectional type.