Patent Grant
10522909
The present disclosure relates to antenna structures for wireless devices. Wireless devices described herein may be used for mobile broadband communications.
Modern devices, such as Wi-Fi routers, often utilize multiple antennas to improve a throughput of the device. However, when multiple antennas are mounted in close proximity, the antennas can interfere with one another, degrading the performance of the antennas.
Embodiments of the present disclosure may include a wireless device a multiple-input multiple-output antenna. A multiple-input multiple-output antenna may include a counterpoise, a first antenna structure, and a second antenna structure. The first antenna structure may include a first parallel resonance element configured to resonate in at least one frequency, a first serial resonance component configured to resonate at a first frequency and configured to couple to the first parallel resonance element, and a first distributed feed element connected to a first feed line and configured to deliver a radiofrequency signal and couple to the first parallel resonance element and the first serial resonance component at the first frequency. The second antenna structure may include a second parallel resonance element configured to resonate in at least one frequency, a second serial resonance component configured to resonate at the first frequency and configured to couple to the second parallel resonance element, and a second distributed feed element connected to a second feed line and configured to deliver a radiofrequency signal and couple to the second parallel resonance element and second serial resonance component at the second frequency. The first parallel resonance element and the second parallel resonance element may be at least partially defined by the counterpoise.
In another embodiment consistent with the present disclosure, a wireless device may include a conductive chassis, a first conductive coupling element having one end connected to the conductive chassis, the first conductive coupling element and the conductive chassis cooperating to form a first slit therebetween, and a first elongate feed element disposed at least partially in the slit between the first coupling element and the chassis. The wireless device may further include a second conductive coupling element having one end connected to the conductive chassis, the second conductive coupling element and the conductive chassis cooperating to form a second slit therebetween, and a second elongate feed element disposed at least partially in the slit between the second coupling element and the chassis. A portion of the first coupling element and the chassis may be configured to couple together and radiate in at least one frequency band when supplied with a radiofrequency signal in the at least one frequency band by the first elongate feed element, and a portion of the second coupling element and the chassis may be configured to couple together and radiate in the at least one frequency band when supplied with a radiofrequency signal in the at least one frequency band by the second elongate feed element.
Reference will now be made in detail to exemplary embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
Embodiments of the present disclosure relate generally to wide bandwidth antennas provided for use in wireless devices. Multi-band antennas consistent with the present disclosure may be employed in mobile devices for cellular communications, and may operate at frequencies ranging from approximately 700 MHz to approximately 2.7 GHz. Multi-band antennas consistent with the present disclosure may further be employed for any type of application involving wireless communication and may be constructed to operate in appropriate frequency ranges for such applications. Multi-band antennas consistent with the present disclosure may function as coupled resonance circuits and as multiple coupled resonance circuits. In some embodiments consistent with the present disclosure, a plurality of multi-band antennas may be provided within a single wireless device to provide multiple-input multiple-output (MIMO) communications.
As used herein, a parallel resonance circuit describes a circuit model having a high impedance and having resonance characteristics, including, for example, resonance frequency and Q factor, being substantially determined by one or more reactive elements arranged electrically in parallel to one another. Q factor, or antenna quality factor, is inversely related to antenna bandwidth. Thus, an antenna having a low Q factor has a high bandwidth. In contrast, a serial resonance circuit describes a circuit model having a low impedance and having resonance characteristics with low impedance being substantially determined by one or more reactive elements arranged electrically in serial to one another. For example, a parallel resonance circuit may include at least one inductive element and at least one capacitive element arranged in parallel to one another. A serial resonance circuit may include at least one inductive elements and at least one capacitive element arranged serially. Both parallel and serial resonance circuits may include further reactive elements that contribute less significantly to the resonance characteristics of the circuit.
Resonating structural elements of an antenna may be modeled as parallel resonance circuits and serial resonance circuits. For example, as used herein, a parallel resonance element and a serial resonance component may be physical structural elements of an antenna. A structure having one or more parallel resonance elements may be electrically modeled as, or may function as, a parallel resonance circuit. As described herein, a structure having one or more serial resonance components may be electrically modeled as, or may function as, a serial resonance circuit. A structure may be configured to function as either a serial resonance circuit or a parallel resonance circuit, depending, for example, on a frequency of radiofrequency signal that is fed to it or on a location of a point at which a radiofrequency signal is fed to it.
Reactive elements of a structure modeled as a resonance circuit may include, for example, capacitors and inductors. Reactive structural elements of a structure modeled as a resonance circuit may also include any other structure that exhibits reactive (e.g., capacitive and/or inductive) characteristics when carrying an electrical signal. Some structures that may function as reactive elements in a resonance circuit may display frequency dependent reactive characteristics. For example, a capacitive structure may display reactive properties when excited by an electrical signal of a first frequency, but may display different reactive properties when excited by an electrical signal of a second frequency. As described herein, reactive elements of structures modeled as resonance circuits display reactive characteristics at frequencies appropriate for wireless communication performed by antennas of which they are a part.
Structures functional as or modeled by both parallel and serial resonance circuits may be included as distinct structures within an antenna, and/or may include antenna portions that serve as portions of more than one element of an antenna. For example, a structure serving as a portion of a parallel resonance element may also serve as a portion of a ground plane element. In another example, a structural serving as a serial resonance component may also as a portion of a coupling element.
Many other dual roles are possible for a single structural element, and are described in more detail herein.
Elements fitting to a resonance circuit model may further include gaps, spaces, slits, slots, and cavities within, near, between, and around structural elements. That is, structural elements modeled as or functional as a resonance circuit need not be defined by a continuous galvanically connected structure. For example, a slot or slit between two structural elements may function as a serial resonance component or parallel resonance element when carrying a radiofrequency signal.
As illustrated in
As with the resonance circuit elements described above, a coupling element functioning as coupling portion 104 may be a distinct structure within a coupled resonance circuit 100, and/or it may be formed from one or more antenna portions that also serve other functions. In some embodiments, a coupling element may include gaps, spaces, slits, slots, and cavities within, near, between, and around structural elements. For example, a serial resonance component having a structural element sufficiently close to a structural element of a parallel resonance element may couple to the parallel resonance element across the gap between structural elements. In such an arrangement, a coupling element may include portions of structural elements from each of the serial resonance component and the parallel resonance element, as well as the gap between them.
As shown in the model illustrated in
In operation, an antenna modeled after coupled resonant circuit 100 may display a Q factor substantially similar the Q factor of the one of two resonance circuits 101 having the lower Q factor. Thus, bandwidth of antenna modeled as a coupled resonance circuit 100 may be determined by the lower Q factor resonance circuit 101.
While the Q factor of the coupled resonance circuit 100 may substantially depend on the Q factor of just one of the resonance circuits 101, the frequency at which resonance circuit 100 resonates may be determined by both parallel resonance circuit 102 and serial resonance circuit 103. Accordingly, an antenna may be designed by using a first resonance circuit 101 having a desirable Q factor and coupling it through a coupling portion 104 with a second resonance circuit 101 having characteristics suitable for adjusting the resonance of coupled resonance circuit 100 to a desirable value.
For example, structural elements modeled as a parallel resonance circuit 102 may have a low Q factor, which may be desirable in a wireless antenna because it provides a wide bandwidth. A structural element of parallel resonance circuit 102 may then be coupled via coupling portion 104 to a structural element of a serial resonance circuit 103 provided to adjust the frequency resonance of coupled resonance circuit 100. Thus, in some embodiments consistent with the present disclosure, a structural element of a parallel resonance circuit 102. e.g., a parallel resonance element, providing a desirable Q factor may be coupled with a structural element of a specific serial resonance circuit 103, e.g., a serial resonance element, for tuning to be used at a specific frequency.
Multi-coupled resonance circuit 200 may operate in a similar fashion to coupled resonance circuit 100. Multi-coupled resonance circuit 200 may be configured such that one of the plurality of serial resonance circuits 103 couples through a coupling portion 104 to one of the at least one parallel resonance circuit 102. The one of the plurality of serial resonance circuits 103, which couples to the at least one parallel resonance circuit 102, may be determined by a frequency of a supplied radiofrequency signal.
For example, a first serial resonance component functioning may be configured to radiate at a first frequency, and may be configured to couple through a coupling element to a parallel resonance element at the first frequency. A second serial resonance component may be configured to radiate at a second frequency, and may be configured to couple through a coupling element to the parallel resonance element at the second frequency. Thus, when an antenna modeled according to the multi-coupled resonance circuit 200 is excited by a signal at the first frequency, the first serial resonance component may couple to the parallel resonance element and radiate at the first frequency. When an antenna modeled according to multi-coupled resonance circuit 200 is excited by a signal at the second frequency, second serial resonance component may couple to the parallel resonance element and radiate at the second frequency.
Further serial resonance components may couple and radiate at additional frequencies. Although
As discussed above, serial resonance components corresponding to serial resonance circuits 103a, 103b, 103c, 103d, may share physical structural components of the antenna and may also share gaps, slots, slits, spaces, windows, and cavities with each other, with the a coupling element corresponding to at least one coupling portion 104 and with a parallel resonance element corresponding to the at least one parallel resonance circuit 102.
In operation, that is, when excited by a radiofrequency signal, different resonance structures modeled as different resonance circuits 101 may be activated, depending on the frequency of the exciting signal. For example, if a combination of one parallel resonance element and one serial resonance component resonates at a particular frequency, then that combination of resonance structures may be activated by a radiofrequency signal having a similar frequency. The activated combination in the a structure modeled after multi-coupled resonance circuit 200 may have a Q factor substantially determined by the activated resonance structure having the lowest Q factor, while the frequency of activation may be determined by the combination of serial resonance component and parallel resonance element that are activated. Thus, a structure modeled after multi-coupled resonance circuit 200 may be configured such that different combinations of resonance structures are activated, depending on the activation frequency. This may permit a designer to optimize performance in specific frequency ranges, by optimizing each resonance structure combination in its activation frequency range.
Achieving the above described selective coupling between one of at least one parallel resonance element and one from among a plurality of serial resonance components may involve the use of a unique coupling element serving as coupling portion 104. A coupling element may be configured to couple radiofrequency signals between the activated parallel resonance element and the activated serial resonance component. The coupling element may be configured to selectively couple a radiofrequency signal between a parallel resonance element and a serial resonance component determined based on a frequency of the radiofrequency signal.
Coupling portion 104 may include a feeding portion 202 for delivering a radiofrequency signal to multi-coupled resonance structure. A feeding portion may carry a radiofrequency signal to or from signal processing portions of a wireless device. The radiofrequency signal carried by the feeding portion 202 may be selected to activate a specific combination of resonance structures. For example, in some embodiments, feeding portion 202 may be configured to activate and couple together a parallel resonance element and a first serial resonance component when supplied with a radiofrequency signal in a first frequency range, and may be configured to activate and couple together the parallel resonance element and a second serial resonance component to radiate in a second frequency range. In such an embodiment, for example, a first frequency range may be a low-band frequency range and a second frequency range may be a high-band frequency range. Feeding portion 202 may enable a coupling element to provide coupling between multiple serial resonance components and at least one parallel resonance element due to unique structural elements, as discussed below with respect to
Wireless device 302 may include a counterpoise 303. Counterpoise 303 may be a conductive element forming at least a portion of a grounding region of antenna 301. Counterpoise 303 may be formed on a substrate and may be formed of various structures within wireless device 302. Counterpoise 303 may include ground edge 315. Ground edge 315 may be, as illustrated in
Counterpoise 303 may form at least a portion of a resonance structure of antenna 301. For example, counterpoise 303 may form at least a portion of a parallel resonance element. In some embodiments, device chassis 304 may include counterpoise 303 and may form at least a portion of a resonance structure.
Counterpoise 303 and wireless device chassis 304 may be configured to be of appropriate electrical lengths to form, each alone or together in combination, at least a portion of a resonance structure. As used herein, electrical length refers to the length of a feature as determined by the portion of a radiofrequency signal that it may accommodate. For example, a feature may have an electrical length of λ4 (e.g., a quarter wavelength) at a specific frequency. An electrical length of a feature may or may not correspond to a physical length of a structure, and may depend on radiofrequency signal current pathways. Features having electrical lengths that appropriately correspond to intended radiation frequencies may operate more efficiently.
Thus, a structural element of antenna 301 may be sized to be of an appropriate electrical length for a frequency range at which the structure is designed to radiate. For example, in an embodiment including a wireless device chassis 304 configured to function as at least a portion of a parallel resonance element, the wireless device chassis 304 may be sized at λ2 (e.g., a half-wave) at an intended activation frequency.
Antenna 301 may include a common conductive element 307. Common conductive element 307 may include a first elongate segment 308, a second elongate segment 309, and a third elongate segment 310. Common conductive element 307 may be configured with more or fewer segments, as may be implemented for specific applications. Common conductive element 307 may share physical structure with other elements of wireless device 302. For example, as illustrated in
Common conductive element 307 may be located so as to form slit 320 between a portion of common conductive element 307 and ground edge 315. Slit 320 may be an elongated slit or gap between common conductive element 307 and ground edge 315. Slit 320 may be an element of coupling portion 104 in multi-coupled resonance circuit 201. The width and length of slit 320 may be varied based on a frequency of operation of a wireless device, for example slit 320 may be between 30 and 45 mm long, and/or may have an electrical length of between 0.06λ and 0.405λ at frequencies between 600 MHz and 2.7 GHz. The width of slit 320 may be between 0.2 and 2 mm and have an electrical length between 0.0004λ and 0.018λ.
Antenna 301 may further include a feeding portion 204 including several elements. Feeding portion 204 may include feed line 306 configured to carry a radiofrequency signal from processing elements of wireless device 301 to a feedpoint 305. Distributed feed element 306 may be coupled, galvanically, reactively, or otherwise, to feedpoint 305. Distributed feed element 306 is pictured in greater detail in the inset image of
When provided with a radiofrequency signal via feed line 306 antenna 301 may operate as follows, as described with respect to
Multi-band properties of antenna 301 may be achieved through the dual function of common conductive element 307 as a serial resonance component in a high band frequency range (e.g., approximately 1.7-2.76 GHz). When activated with a radiofrequency in this higher frequency range, the structure defined by common conductive element 307 and slot 325 may radiate as a quarter wavelength slot antenna, with representative slot antenna current pathway 403 as illustrated in
An exemplary graph of the multiband performance of antenna 301 as illustrated in
The achievement of multi-band performance and the dual radiation function of common conductive element 307 may be at least partially attributed the folded nature of common conductive element 307 and to the nature of distributed feed element 306.
First, in order to radiate as a quarter wave monopole at two different frequency ranges, common conductive element 307 may define radiating structures having two different electrical lengths corresponding to the frequency ranges. These two electrical lengths may be achieved by establishing two alternate current pathways 402, 403. As illustrated in
Second, in order to radiate as a quarter wave monopole at two different frequency ranges, the monopole may use two different feed points. In conventional quarter wave monopole designs, an antenna may be fed at a feed location on one end, and the feedline may be sized to deliver a radiofrequency signal having appropriate current characteristics at the feedpoint. Such a design may, however, may face significant performance drops when supplied with a radiofrequency signal outside of the design frequency. Distributed feed element 306 may address this issue by providing a range of potential feeding locations throughout its length. In operation, radiofrequency signals of different frequencies (and different wavelengths) may therefore couple from distributed feed element 306 to common conductive element 307 at different points along the portion of distributed feed element 306 located in proximity to common conductive element 307.
a-4d illustrate one particular physical embodiment of the coupled resonance circuit concepts described by this disclosure. Alternative physical embodiments may be designed and implemented to achieve an antenna with various parameters without departing from the spirit and scope of this disclosure.
In the embodiment of
Operating at low-band frequencies, antenna 901 may include a parallel resonance element, formed from at least a portion of counterpoise 303 and/or wireless device chassis 304. The parallel resonance element may couple through a coupling element at least partially formed by distributed feed 306 to either one of a pair of serial resonance components. The coupling element may include base portion 905 of radiating element 907, ground edge 315, and distributed feed element 306. A first serial resonance component of antenna 901 may include a current pathway 406 as illustrated in
Operating at high-band frequencies, antenna 901 may also include a plurality of serial resonance components. A first high-band serial resonance component may include looped current pathway 408, traveling around base portion 905, connection portion 904, second branch 902, and loop portion 911. A second high-band serial resonance component may include current pathway 409, traveling through loop portion 911 and into extension 906. High-band performance may be further augmented by harmonics of the low-band radiating structures. For example, a low-band radiating structure, having current pathway 406 or 407, may be configured to resonate at approximately 700 MHz. In such a case, the structure may also radiate at a third harmonic, at approximately 2.1 GHz. The performance of antenna 901 is illustrated by return loss graph 950, as shown in
Antenna 1001 may be considered a variation of antenna 901. In the low-band frequency ranges, antenna 1001 may include a serial resonance component having a current pathway 414 that extends from base portion 1005, across second connecting portion 1008, and along second branch 1012. This pathway is similar to current pathway 406 of antenna 901. The addition of slot 1013 may eliminate a current pathway similar to current pathway 407 of antenna 901, leaving just one low-band frequency current pathway 406 which may follow base portion 1005, second connecting portion 1008, and second branch 1012. The slot 1013, however, may also permit an additional serial resonance component in the high-band frequency ranges by creating current pathway 410 in slot 1009, which may function as a quarter wave slot antenna.
Current pathways 411 and 412 may define additional serial resonance components, operating similarly to current pathways 409 and 408, respectively. As illustrated in return loss graph 1050 of antenna 1001 as compared to return loss graph 950 of antenna 901 in
Any of the above-described antennas may be combined with other such antennas in a single device to implement a multi-input multi-output (MIMO) antenna and provide for MIMO communications. In general, MIMO antennas and associated communication devices multiply the capacity of a wireless communication link by using multiple antenna structures that are configured to work together to exploit multipath propagation techniques. For example, a MIMO antenna with two antenna structures can transmit double the data throughput using MIMO communication techniques compared to a single antenna. These MIMO antennas and multipath propagation techniques thus can facilitate the simultaneous sending and/or receiving of more than one data signal on the same frequencies via multipath propagation.
In general, MIMO antennas in accordance with the embodiments described herein are implemented to include multiple antenna structures, where the multiple antenna structures share a common radiating element in a way that facilitates MIMO operation. In some embodiments the shared radiating element comprises a shared antenna counterpoise. Furthermore, in some of these embodiments the shared radiating element is formed from the chassis of an associated wireless communication device.
To provide effective MIMO communication, the multiple antenna structures are configured in a way that reduces coupling between the antenna structures. Specifically, the antenna structures are configured to reduce coupling in the shared radiating element (e.g., shared chassis or counterpoise used as a shared radiating element). Reducing the coupling between antenna structures reduces interference, and thus can improve usable bandwidth and MIMO communication functionality.
For example, the coupling between antenna structures that share a radiating element can be reduced in some embodiments using the relative spacing of the antenna structures and the shared radiating element. In other embodiments the shape and structure of the radiating element is configured to reduce coupling between antenna elements. For example, projecting structures that extend from a surface of the radiating element can be used to reduce coupling.
A variety of different types and configurations of antenna structures can be used in such MIMO antennas. For example, the various antennas described above can be implemented with a shared radiating structure to provide MIMO communication. As one specific example, each antenna structure in the MIMO antenna can include a first parallel resonance element configured to resonate in at least one frequency, a first serial resonance component configured to resonate at a first frequency and configured to couple to the first parallel resonance element, and a first distributed feed element connected to a first feed line and configured to deliver a radiofrequency signal and couple to the first parallel resonance element and first serial resonance component at the first frequency. In a typical implementation multiple of such antenna structures can be configured together with a shared radiating element to provide MIMO communication. Specifically, in some embodiments the parallel resonance elements of the multiple antenna structures can each be at least partially defined by a counterpoise that functions as a shared radiating element.
As another specific example, the MIMO antenna can be provided that uses a shared conductive chassis as a radiating element. In such an embodiment the multiple antenna structures implemented to share the conductive chassis as a radiating element can each include a conductive coupling element having one end connected to the conductive chassis, where the conductive coupling element and the conductive chassis cooperating to form a first slit therebetween, and an elongate feed element disposed at least partially in the slit between the coupling element and the conductive chassis.
Antenna structure 1101 as illustrated includes a counterpoise 303 having a ground edge 315, a feed point 305, a feed line 350, a distributed feed element 306, and a radiating element 1107. The feed line 350 is suitably coupled (e.g., soldered) to the feed point 305 and the counterpoise 303. For example, the feed line 350 can comprise a coaxial cable, with the center conductor of the feed line 350 soldered to the feed point 305 and the conductive outer shield soldered to the counterpoise 303. Distributed feed element 306 may have a first branch 1120 and a second branch 1121. Radiating element 1107 may include a loop portion 1103, an extension 1102, a first connection portion 1104, a second connection portion 1105, and a central portion 1106. Loop portion 1107 may include a first coupling portion 1108 and a second coupling portion 1109. Radiating element 1107 may cooperate with distributed feed element 306 to form at least one slit, including, for example, first slit 1130 and second slit 1131. Loop portion 1107 may also define a slot 1140.
To facilitate operating at low-band frequencies, the antenna structure 1101 may include a parallel resonance element, formed from at least a portion of counterpoise 303 and/or a wireless device chassis (not shown). Such a parallel resonance element may couple through a coupling element at least partially formed by distributed feed 306 to serial resonance components formed by radiating element 1107. The coupling element may include either or both of first and second coupling portions 1108 and 1109, ground edge 315, and either or both of first branch 1120 and second branch 1121 of distributed feed element 306.
When configured to operate at relatively high-band frequencies, antenna structure 1101 may also include a plurality of serial resonance components formed from portions of radiating element 1107 and configured to couple through a coupling element to a parallel resonance element formed at least partially from counterpoise 303 and/or a wireless device chassis. As one specific example, low-band radiating structures consistent with antenna structure 1101 may be configured to resonate in a frequency band between 550 and 1000 MHz. Likewise, high band radiating structures consistent with the antenna structure 1101 may be configured to resonate in a frequency band between 1700 and 2700 MHz.
In some embodiments, antenna structure 1101 may share counterpoise 303 and a device chassis with one or more other, similar antennas structures 1102, 1103, 1104 to function as a MIMO antenna 1201. An example of such an embodiment is illustrated in
In
In the example of
Additionally, in the embodiment of
Again, each current limiting structure 1603 can include an extension from the counterpoise 303 surface, with the length of the extension selected to form a preferred current path for RF current. Specifically, the length of the extensions can be selected to form resonant structures with antenna structures 1103 and 1104 even though those antenna structures are on opposite sides of the printed circuit board. For antenna structures 1101 and 1102, the distance from the extensions is again relatively large, the current intensity is thus relatively low, and the extensions would thus not resonate with those antenna structures.
In such an embodiment, the corner locations of antenna structures 1101 and 1103 can cause the radiation pattern resulting from associated currents to tilt. Specifically, the radiation pattern caused by currents in the counterpoise 303 from one antenna structure can tilt to the left, while the radiation pattern for the other antenna structure tilts to the right. This tilting in different directions reduces the coupling caused by the currents and associated radiation patterns.
Additionally, the asymmetric location of the antenna structure 1102 will also alter the resulting current induced radiation pattern. These altered radiation patterns can also increase the isolation between antenna structures, allowing even smaller sized counterpoises and associated devices. However, in some cases this can also result in less than ideal radiation patterns.
In one embodiment, a multiple-input multiple-output antenna is provided, the antenna comprising: a counterpoise; a first antenna structure, the first antenna structure including: a first parallel resonance element configured to resonate in at least one frequency, a first serial resonance component configured to resonate at a first frequency and configured to couple to the first parallel resonance element, and s first distributed feed element connected to a first feed line and configured to deliver a radiofrequency signal and couple to the first parallel resonance element and first serial resonance component at the first frequency; and a second antenna structure, the second antenna structure including: a second parallel resonance element configured to resonate in at least one frequency, a second serial resonance component configured to resonate at the first frequency and configured to couple to the second parallel resonance element, and a second distributed feed element connected to a second feed line and configured to deliver a radiofrequency signal and couple to the second parallel resonance element and second serial resonance component at the second frequency, wherein the first parallel resonance element and the second parallel resonance element are at least partially defined by the counterpoise.
In another embodiment, a wireless device is provided comprising: a conductive chassis; a first conductive coupling element having one end connected to the conductive chassis, the first conductive coupling element and the conductive chassis cooperating to form a first slit therebetween; and a first elongate feed element disposed at least partially in the slit between the first coupling element and the chassis; a second conductive coupling element having one end connected to the conductive chassis, the second conductive coupling element and the conductive chassis cooperating to form a second slit therebetween; and a second elongate feed element disposed at least partially in the slit between the second coupling element and the chassis; wherein a portion of the first coupling element and the chassis are configured to couple together and radiate in at least one frequency band when supplied with a radiofrequency signal in the at least one frequency band by the first elongate feed element, wherein a portion of the second coupling element and the chassis are configured to couple together and radiate in the at least one frequency band when supplied with a radiofrequency signal in the at least one frequency band by the second elongate feed element.
The foregoing descriptions of the embodiments of the present application have been presented for purposes of illustration and description. They are not exhaustive and do not limit the application to the precise form disclosed. Modifications and variations are possible in light of the above teachings or may be acquired from practicing the disclosed embodiments. For example, several examples of antennas embodying the inventive principles described herein are presented. These antennas may be modified without departing from the inventive principles described herein.
Additional and different antennas may be designed that adhere to and embody the inventive principles as described. Antennas described herein are configured to operate at particular frequencies, but the antenna design principles presented herein are limited to these particular frequency ranges. Persons of skill in the art may implement the antenna design concepts described herein to create antennas resonant at additional or different frequencies, having additional or different characteristics.
Other embodiments of the present application will be apparent to those skilled in the art from consideration of the specification and practice of the embodiments disclosed herein. It is intended that the specification and examples be considered as exemplary only.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 62/111,089, filed Feb. 2, 2015, the entire content of which is incorporated by reference herein.
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