The subject matter disclosed herein relates generally to antenna systems, devices, and methods. More particularly, the subject matter disclosed herein relates to antenna designs for use with radio communications systems, devices, and methods.
The fourth Generation (4G) of mobile communications standardized Long Term Evolution (LTE) and LTE-Advanced (LTE-A) technologies in order to provide higher data rates to consumers. 4G is being deployed on new and different frequency bands around the globe, however, which has led to band proliferation. Consequently, where it is desired for users to be able to maintain connectivity over any of these 4G frequency bands, device antennas need to cover about 40 bands in Frequency Division Duplex (FDD) and Time Division Duplex (TDD), with the number of bands likely to increase further in future generations. In this regard, world-wide mobile data access has multiplied the number of bands allocated to mobile communication by a factor of ten compared to speech-only specifications (e.g., 2G). Specifically, fourteen bands are defined in the low frequency range of the 4G spectrum today and represent nearly all the frequencies between 699 MHz and 960 MHz. Additionally, part of the frequency spectrum previously used for television broadcasting in frequencies ranging from 600 MHz to 698 MHz is being put up for auction to carriers, and still lower frequencies are being considered.
Designing a handset antenna in the low bands of 4G has shown to be a challenge for antenna engineers, as the antenna bandwidth and operating frequency vary inversely proportionally with the antenna volume provided a constant efficiency. Thus, to both lower the antenna resonance frequency and to enhance its bandwidth, the antenna volume needs to be increased. Conversely, however, consumer demand for smaller and slimmer designs, along with the drive to fit more components into smart-phones (e.g., cameras, large battery, high-end screen), incentivizes device manufacturers to develop antenna footprints that are as small as possible for newer generations of smart-phones. As a result, over the past decade, antenna engineers have pushed the low bound of their design from 824 MHz to 699 MHz while at the same time reducing the antenna volume. This combination of low resonance frequency and smaller antenna volume can often cause efficiency degradation, which impacts communication performance. These problems may be further exacerbated by attempts to utilize the new bands available in the low band, which have to be pushed by an extra 100 MHz.
Accordingly, it would be desired for antenna systems, devices, and methods to provide efficient coverage of low frequency bands (e.g., 700 MHz-bands and 600 MHz-bands) for the new generations of mobile communication.
In accordance with this disclosure, antenna systems, devices, and methods for use with radio communications systems, devices, and methods are provided. In one aspect, a multiple-resonant radiating system is provided. Such a system can include a ground plane, a radiating coupler spaced apart from but in communication with the ground plane, and a ground plane extension in communication with the ground plane. In this arrangement, one or both of the radiating coupler and the ground plane extension are tunable to tune a multiple-resonance frequency response.
In another aspect, a multiple-resonant radiating system comprises a ground plane, a radiating coupler spaced apart from but in communication with the ground plane, a first tunable element connected between a coupler connection of the radiating coupler to the ground plane and a ground, a series tunable capacitor connected between the coupler connection of the radiating coupler to the ground plane and a feed node, a ground plane extension in communication with the ground plane, and a second tunable element connected to the ground plane extension. In this configuration, the first tunable element and the series tunable capacitor can be configured to tune a resonant frequency of the radiating coupler, and the second tunable element can be configured to tune a resonant frequency of the ground plane.
In yet another aspect, a method for operating an antenna is provided. The method can include tuning a first resonant frequency of a radiating coupler that is spaced apart from but in communication with a ground plane and tuning a second resonant frequency of a combination of the ground plane and a ground plane extension that is in communication with the ground plane. In this way, the first resonant frequency and the second resonant frequency can add constructively to form a multiple-resonance frequency response. In addition, a further benefit of the present systems and methods is that the ground can be tuned to a lower frequency to match the antenna operating frequency, which can leads to enhanced efficiency.
Although some of the aspects of the subject matter disclosed herein have been stated hereinabove, and which are achieved in whole or in part by the presently disclosed subject matter, other aspects will become evident as the description proceeds when taken in connection with the accompanying drawings as best described hereinbelow.
The features and advantages of the present subject matter will be more readily understood from the following detailed description which should be read in conjunction with the accompanying drawings that are given merely by way of explanatory and non-limiting example, and in which:
To provide mobile high-speed internet as well as calling experiences world-wide, it can be desirable that the mobile device antenna is configured to cover a bandwidth of 360 MHz in the low bands of 4G (i.e., 600 MHz to 960 MHz). With this range of over 300 MHz of tuning for the antenna resonance frequency, it is understood that the antenna Quality factor (Q) increases as the antenna is tuned, which can cause the bandwidth to decrease. Although the instantaneous bandwidth needed for future systems at 600 MHz is still undetermined, the channel bandwidths of existing 4G bands range between 1.4 MHz and 20 MHz. Accordingly, with the duplex spacing being likely to be between 10 MHz and 40 MHz, the required antenna bandwidth could be 60 MHz at 600 MHz. Those having skill in the art will recognize that it is a major challenge to make an efficient design for this specification in a typical smart-phone form factor.
Accordingly, the present subject matter provides a design that combines a tunable antenna and a tunable ground plane (GP) extension in order to create a multiple-resonance antenna. The multiple-resonance concept is used to cover transmitting (TX) and receiving (RX) channels, which exhibit a large duplex spacing in low frequency bands (e.g., 600 MHz-bands may have 40 MHz duplex and 20 MHz channels). As a result, duplex spacing is not an issue and only the channel bandwidth needs to be covered with one antenna resonance.
In one aspect, the present subject matter provides an antenna design that achieves a multiple-resonance frequency response. In one exemplary configuration illustrated in
In some embodiments, both of radiating coupler 120 and ground plane extension 130 can be provided as planar inverted L antennas (ILA) that are in communication with ground plane 110. Specifically, for example, in the particular configuration illustrated in
Alternatively, those having skill in the art will recognize that the dimensions of radiating coupler 120 and ground plane extension 130 can be modified based on the particular design constraints of a given device (e.g., smaller elements may be desired in order to enhance compactness). As discussed above, the size of the elements is general inversely proportional to the achievable bandwidth of the antenna. Additionally, the size of the elements can further be inversely proportional to the values of tuning elements (e.g., tunable capacitors and/or inductors) in the circuitry that allow the frequency band of antenna 100 to be tuned. Accordingly, those having ordinary skill in the art will recognize that several combinations of antenna geometry, capacitance, and inductance can achieve the same or similar multiple-resonance frequency response.
Moreover, in some embodiments, radiating coupler 120 and ground plane extension 130 need not be symmetrical in order to constructively add their frequency response. For example, ground plane extension 130 can exhibit a more compact design to reduce the total volume of antenna 100 and/or ground plane extension 130 can provide a more robust connection to ground plane 110, while the configuration of radiating coupler 120 remains unchanged, and the multiple-resonance capabilities of antenna 100 are maintained. In addition, in some embodiments, radiating coupler 120 and ground plane extension 130 are not co-located (e.g., radiating coupler 120 can be connected at the top of ground plane 110 and ground plane extension 130 can be connected at the bottom of ground plane 110).
In any configuration, radiating coupler 120 can be configured to resonate at a desired high bound (e.g., about 900 MHz corresponding to a high bound of the LTE band) and can be tuned to lower frequencies (e.g., about 600 MHz corresponding to a low bound of the LTE bands). Ground plane 110 is also put in resonance, which can be lowered by the connection of ground plane extension 130 (e.g., to about 900 MHz as well). Furthermore, in some embodiments, ground plane extension 130 can be tuned so that ground plane 110 effectively becomes electrically larger, and its resonance frequency can thereby be decreased (e.g., to about 600 MHz). These two independently tunable resonances of the radiation coupler 120 and the combination of ground plane 110 and ground plane extension 130 can add constructively to form a dual resonance and enhance the antenna bandwidth. This additive resonance can be particularly beneficial for elements operating at frequencies at which the radiation parts are smaller than a quarter of the operating wavelength. In particular, as discussed above, coverage at low resonance frequencies with small antennas is challenging because the antenna bandwidth reduces as the antenna becomes electrically smaller (i.e., when the operating frequency decreases). Accordingly, this configuration of antenna 100 makes it possible to more efficiently cover 700 MHz-LTE-bands and to offer coverage to 600 MHz-bands with a wide duplex spacing, all while keeping a low profile. In fact, in some embodiments, the efficiency is enhanced by about 2 dB when the ground plane extension is used.
In addition, although
To achieve this tuning, one or more tunable elements can be provided in communication with one or both of radiating coupler 120 and/or ground plane extension 130. In particular, for example, radiating coupler 120 can be tuned with a first tunable element 122 that is connected between coupler connection 121 and a ground. In one particular configuration shown in
Furthermore, in addition to first tunable element 122, tuning can also be provided by a series tunable capacitor 128 connected between coupler connection 121 and a feed node 123. Series tunable capacitor 128 can be provided as a single tunable capacitor, as a parallel combination of a fixed capacitor and a tunable capacitor, as a series combination of a fixed capacitor and a tunable capacitor, or in any other known configuration for achieving a desired tunable capacitance.
In some embodiments, to help maintain a compact design for antenna 100, radiating coupler 120 can be shaped to follow the edges of the cover of the mobile device in which antenna 100 is provided, and one or more of first tunable element 122 (e.g., including first fixed inductor 124 and first tunable capacitor 126) and series tunable capacitor 128 can be low profile components that can be positioned between radiating coupler 120 and ground plane 110. In this way no cut-back in ground plane 110 is needed to accommodate radiating coupler 120 and/or its tuning elements.
Regardless of the particular configuration, first tunable element 122, either alone or in combination with series tunable capacitor 128, can be configured to achieve desired values for capacitance and inductance corresponding to a desired tuning state for radiating coupler 120. In one embodiment, for example, values of the tuning elements can provide about 5.5 pF maximum capacitance (e.g., with tuning steps of about 0.1 pF) and about 6 nH inductance for radiating coupler 120. Those having ordinary skill in the art will recognize, however, that the values needed for these elements can be selected based on the particular dimensions and configurations of radiating coupler 120, as the relationship between the tuning values and the achievable bandwidth and efficiency can vary with different antenna geometries.
Similarly, ground plane extension 130 can be tuned with a second tunable element 132 that is connected between ground plane extension 130 and ground plane 110. In particular, for example, second tunable element 132 can comprise a second fixed inductor 134 that is connected in parallel with a second tunable capacitor 136 between ground plane extension 130 and ground plane 110. Alternatively, second tunable element 132 can be any of a variety of other element that is tunable to achieve a desired inductance, including for example a series combination of a fixed inductor and a tunable capacitor. In any arrangement, second fixed inductor 134 can be formed using the metal structure used to form ground plane extension 130 itself (i.e., part of the copper used to form ground plane extension 130, which can improve efficiency and simplify the circuitry), it can be formed using wire, or it can be formed using any other known configuration. As with the tuning components connected to radiating coupler 120, in some embodiments, to help maintain a compact design for antenna 100, ground plane extension 130 can be shaped to follow the edges of the mobile device, and second tunable element 132 (e.g., including second fixed inductor 134 and second tunable capacitor 136) can be positioned between ground plane extension 130 and ground plane 110.
Regardless of the particular configuration, second tunable element 132 can be configured to achieve desired values for capacitance and inductance corresponding to a desired tuning state for ground plane extension 130. In this way, for example, as the value of the inductance of second tunable element 132 varies, the electrical length of ground plane 110 varies, and thus the resonance of ground plane 110 can be tuned. In one embodiment, for example, values of the inductance of second tunable element 132 can be varied between about 6 nH to about 26 nH to achieve resonance shifting from 930 MHz to 600 MHz for ground plane 110. Those having ordinary skill in the art will recognize that the values needed for these elements can be selected based on the particular dimensions and configurations of ground plane 110 and ground plane extension 130, as the relationship between the tuning values and the achievable bandwidth and efficiency can vary with varying antenna dimensions. In the case of any of first tunable element 122, series tunable capacitor 128, and/or second tunable element 132, the tunable capacitances can be realized with Micro-Electro-Mechanical Systems (MEMS) tunable capacitors, semiconductor technologies, variable dielectrics, or a combination of these. For example, MEMS devices are considered state of the art in terms of insertion loss, footprint, and voltage handling, which thus makes the technology a great candidate for tunable antennas. Regardless of the particular configuration, antenna 100 can be able to cover all the bands from 960 MHz (upper GSM limit) to 600 MHz (lowest LTE frequency planned) in 4 tuning stages. In addition, each resonance can be independently tunable, allowing for different duplex spacing values.
With antenna 100 being configured as discussed above to achieve a dual-resonance response, an enhanced bandwidth can be achieved that is enough to simultaneously cover TX and RX channels at low frequencies (e.g., 600 MHz-bands) while keeping an acceptable volume from the perspective of phone manufacturers. This design can be configured to optimize the resonance so that maximum efficiency is obtained at the operating channels and not in the frequency range between them. Furthermore, since antenna tuning decreases the antenna bandwidth as the antenna is tuned further away from its natural resonance, dual-resonance antenna systems and devices as discussed above can enhance the bandwidth, and independent tunability of each resonance allows for non-continuous coverage of both TX and RX channels, which can be desirable to cope with wide duplex spacing and optimize efficiency at operating frequencies only. As a result, the present subject matter can make coverage on 600 MHz-bands more practical, and it can make coverage on 700 MHz-bands more efficient, all without the need for a cut-back for the antenna.
Specifically, for example, simulation results for the tunability of antenna 100 are provided in
In comparison,
The contribution of each component to the total loss can be isolated. Specifically, radiating coupler 120 and ground plane extension 130 have different reactances and different current densities, which explains the difference in dissipated power. Moreover, the power dissipated by second fixed inductor 134 differs between the reference configuration tested to obtain the measurements in
Furthermore, using an efficiency threshold of −5 dB, an efficiency bandwidth can be determined. For comparison, the free space Total Radiated Power (TRP) can be between 23 dBm and 31 dBm in the GSM-900 bands for common phones in the market today, and the antenna total efficiency is calculated to average at −4 dB on those bands. For the dual-resonance configuration described herein, however, the measurements show an antenna total efficiency spreading from −3 dB to −7 dB in the GSM-900 bands. The antenna total efficiency at 700 MHz has been reported to peak at −5 dB for the main antenna and −7 dB for the secondary antenna. Therefore, a threshold of −5 dB for evaluating the efficiency bandwidth is realistic, though a tough requirement at 600 MHz. The efficiency bandwidths of this design vary from 205 MHz to 20 MHz. Naturally, as the threshold is lowered the efficiency bandwidth increases. However, the higher the peak efficiency, the wider the efficiency bandwidth for a given threshold.
Compared to the reference design, the use of ground plane extension 130 can enhance the peak total efficiency by about 1.8 dB. Consequently, the efficiency bandwidth at −5 dB for the furthest tuning stage, i.e. state 5, becomes 20 MHz. From an application point of view, the LTE bands 5, 6, 8, 13, 14, 18, 19, 20, 26 and 27 are covered in one operating state, and the LTE bands 12,17 are covered in another operating state.
Referring now to the graphs illustrated in
Referring now to
That being said, it is noted that simulated efficiencies include mismatch loss, loss from the tuner, and from the fixed inductors. From practical experience, measured efficiencies can be as much as about 1 dB below simulated efficiencies due to thermal loss inaccuracies in the simulator. Even so, the values expected are still very good compared to phones in the market nowadays. With a finer simulation, one can see the dual-resonance response on the efficiency curve. The change in efficiency is due to mismatch loss. Additionally, different tuning settings can vary the resulting efficiency (e.g., due to parasitics).
The present subject matter can be embodied in other forms without departure from the spirit and essential characteristics thereof. The embodiments described therefore are to be considered in all respects as illustrative and not restrictive. Although the present subject matter has been described in terms of certain preferred embodiments, other embodiments that are apparent to those of ordinary skill in the art are also within the scope of the present subject matter.
The present application is a continuation patent application of U.S. patent application Ser. No. 14/885,779, filed Oct. 16, 2015, which claims the benefit of U.S. Provisional Patent Application Ser. No. 62/065,106, filed Oct. 17, 2014, the disclosures of which are incorporated herein by reference in their entireties.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 14885779 | Oct 2015 | US |
Child | 16189769 | US |