Patent Application
20130321212
1. Field of the Invention
This invention relates to antennas and methods for use in wireless communications. More particularly, the invention relates to antennas having one or more monopole type elements adapted for multiple resonance signaling and being configured on a flexible substrate for volumetric configuration of the antenna within a wireless communication system, and related methods for fabrication and tuning thereof.
2. Description of the Related Art
As trends in wireless communication technology continue to rapidly develop, the design trend in current portable electronic devices such as laptop computers, mobile phones, and personal digital assistants (PDAs) continues to move toward lighter and thinner device attributes. As such, antennas for use in these portable electronic devices are collaterally affected by these trends and presently require reductions in antenna volume and other physical attributes while maintaining or enhancing performance characteristics in an effort to meet manufacturer and consumer expectations.
Moreover, additional frequency bands are being required for portable communication devices, making the antenna design effort increasingly difficult. To cover these additional frequency bands, multiple resonances are required from the antenna, and positioned in frequency to provide efficient transmission and reception. This requirement for multiple resonances excludes certain antenna types from being implemented.
Conventional monopole type antennas provide a single resonance that can be tuned to cover a single frequency band. A primary benefit of a monopole antenna is the ability to work well in close proximity to a ground plane, making this type antenna conducive to use in commercial communication devices for portable applications. Additional resonances are generated from a monopole, which are harmonics of the dominant resonance. These harmonics occur at integer multiples of the fundamental resonance, however with little ability to shift the frequency response to effectively transmit or receive at additional frequency bands. This limitation in the ability to generate and control additional resonances from monopole antennas in a small size continues to present a longstanding problem in the art.
Monopole antennas can be fabricated using many types of manufacturing technology. The monopole can be printed on a printed circuit board (PCB) in the form of a copper foil displayed in a two dimensional shape, or can be provided as a three dimensional design from metal sheet forming processes. The two dimensional shape lends itself to photo-etching techniques on PCBs and aids in integration into portable electronic devices due to reduced volume of the two dimensional design.
Monopole antennas require a feed signal to operate, the feed signal typically provided by a transmission line, and the distance from the monopole to the ground plane is critical for the tuning the monopole antenna. Connecting the center conductor of a transmission line to the monopole and the ground connector of the transmission line to the ground plane can be difficult for monopole antennas used within a portable device, which is why many devices continue to comprise external-type monopole antennas which extend outward from the device housing. In practice, volumetric placement of the monopole is restricted within a device due to the requirement of grounding the conductor of the transmission line to the ground plane of the PCB of the portable device. A separate coaxial connector can often be required at the feed point of the monopole to provide reliable and consistent connection of the transmission to the ground plane of the PCB.
With the ongoing need for small, lightweight, and low cost antennas in wireless devices, and with the additional requirement of covering several frequency bands, a method of integrating and connecting to a multiple resonance antenna is required. In order to utilize monopole type antennas in view of the continuing trends, a method for implementing a second resonance of a monopole antenna is needed to provide the additional resonance for additional frequency coverage as required by modem trends.
In view of the above limitations in the art, a monopole type antenna is provided for use in wireless communications systems, the monopole type antenna comprises two resonant sections for accommodating multiple application requirements of modem wireless communications systems. The dual resonances of the two resonant sections may comprise a high frequency resonance and a low frequency resonance. Moreover, the dual resonance monopole is disposed on a flexible substrate for providing a bendable volumetric configuration of the antenna for altering various characteristics such as impedance and frequency response and providing dimensional tuning of the antenna within a confined space of a portable communications device.
In one embodiment, one or more conductors of the antenna architecture are volumetrically positioned to enhance harmonics of the monopole type radiator for providing additional resonances for use in applications of modern devices.
In another embodiment, two or more conductors of the antenna architecture are volumetrically positioned in orthogonal relation for providing two or more resonances for use in applications of modem devices.
In yet another embodiment, a method is provided for fabricating and tuning a monopole type antenna for use with modem communications systems.
Other features and advantages will become apparent to those having skill in the art upon further review of the appended detailed description of the various embodiments.
In the following description, for purposes of explanation and not limitation, details and descriptions are set forth in order to provide a thorough understanding of the present invention. However, it will be apparent to those skilled in the art that the present invention may be practiced in other embodiments that depart from these details and descriptions.
In a general embodiment, a volumetrically configurable dual resonance monopole antenna comprises a substrate, a radiating structure disposed on the substrate, and a grounding strap. The substrate is formed from a thin-sheet of dielectric material. The sheet of material is adapted for flexible configuration, or bending, and has a first planar surface and a second planar surface opposite of the first planar surface. The radiating structure disposed on the substrate comprises a monopole-type radiator having a first resonant section adapted to radiate at a first frequency (f1) and a second resonant section adapted to resonate at a second frequency (f2). The first and second resonant sections are connected at a common feed. The grounding strap comprises at least a first grounding portion disposed on the first planar surface of the substrate and a second grounding portion disposed on the second planar surface of the substrate opposite of the first planar surface. The first and second portions of the grounding strap are connected by a plurality of thru vias extending through the substrate from the first planar surface to the second planar surface. In this regard, the radiating structure is adapted for volumetric configuration by bending the flexible substrate and radiating structure thereon to yield desired impedance and radiation characteristics of the resulting structure.
In one embodiment, a single integrated assembly comprises a dual resonance monopole antenna with integrated coaxial transmission line and ground connection. With the antenna and ground connection fabricated on a single substrate, antenna attachment to a PCB of a wireless or portable device is enhanced.
In another embodiment, a feed conductor is used to feed two antenna radiator sections. Each of the antenna radiator sections can be individually adjusted by configuring size, shape, and position about a substrate in order to radiate at a desired frequency. The two antenna radiator sections may comprise a low frequency conductor and a high frequency conductor, wherein the low frequency conductor is relatively larger than a high frequency conductor. The low frequency conductor can be adjusted to resonate at a first frequency (f1), while the high frequency conductor can be adjusted to resonate at a second frequency (f2) such that f2 is distinct from f1. The first frequency (f1) is generally lower than the second frequency (f2), due to the relatively larger size of the low frequency conductor relative to the high frequency conductor. All three of the antenna conductors can be fabricated on a single substrate, and this substrate can be flexible to allow for forming into a three-dimensional shape. The feed conductor, low frequency conductor, and high frequency conductor yield a three-conductor embodiment.
In this regard, the feed conductor being connected to the low and high frequency conductors provides a dual resonance monopole, wherein the antenna comprises a first resonance at the low frequency conductor and a second resonance at the high frequency conductor, each being commonly connected at a junction with the feed conductor.
In another embodiment of the present invention, a transmission line, such as a coaxial transmission line, can be connected to the dual resonant monopole. The center conductor, or “feed connector” of the transmission line is connected to the feed conductor of the dual resonant monopole. The “ground connector”, or the outer conductor in the case of a coaxial transmission line, can be connected to the reference ground of the circuit, printed circuit board (PCB), or other ground plane available for connection.
In another embodiment, a fourth conductor is added to the three conductor embodiment described above, with the fourth conductor used as a ground connection or “ground strap”. This fourth conductor can be connected to the ground connnector of the transmission line, with the ground connector being further connected to a reference ground of the host device. The fourth conductor, or ground strap, can be fabricated on the same single substrate as the other three conductors (radiators). The ground strap can be fabricated on opposing sides of the substrate, with the portions of the ground strap connected to each other by way of plated thru vias extending through the substrate.
In another embodiment, the substrate can be bent into a curved surface such that the high frequency conductor of the dual resonant monopole can be positioned in a plane that is predominately orthogonal to the ground plane of the portable device, whereas the low frequency conductor of the dual resonant monopole can be positioned in a plane that is predominately co-planar to the ground plane of the portable device. The orientation of each conductor of the dual resonance monopole can be used to alter the resonant frequency, impedance, radiation patterns, and radiation efficiency of the monopole.
In another embodiment, the substrate can be flexible and bent into a curved surface such that the high frequency conductor of the dual resonant monopole can be positioned in a plane that is predominately co-planar to the ground plane of the portable device, whereas the low frequency conductor of the dual resonant monopole can be positioned in a plane that is predominately orthogonal to the ground plane of the portable device. The orientation of each conductor of the dual resonant monopole can be used to alter the resonant frequency, impedance, radiation patterns, and radiation efficiency of the monopole.
In certain embodiments, at least one of the first and second resonant sections of the radiating structure is disposed in a common plane with the host device ground plane.
In another embodiment, the length of and separation distance, or “gap”, between the ground conductor and the high frequency and low frequency conductors of the dual monopole can be adjusted to change the radiation pattern of the first frequency (f1) and/or the second frequency (f2) when the dual monopole antenna is not connected to the ground plane of the portable device.
A detailed description of the invention will now be made with reference to the accompanying drawings, wherein:
a-b) illustrate a dual resonance monopole assembly 12 comprising a high frequency conductor and a low frequency conductor disposed on a single substrate with a transmission line 7 connected to a common feed of the monopole radiator. The ground conductor 17 is configured with a desired length and separation distance from the radiating conductor for tuning the radiating characteristics of the antenna. Note that a first grounding strap portion is disposed further away from a low frequency radiating portion of the antenna; whereas a second grounding strap portion comprises a shorter length than the first grounding strap portion and is positioned closer in proximity to the high frequency radiating portion, respectively. In this regard, the low frequency and high frequency resonances are tuned to yield the desired characteristics of the antenna. Moreover, with the shortened length of the second grounding portion, the reverse side of the assembly is adapted with a shortened grounding strap 8 as illustrated in
a-e) illustrate a number of respective examples of various conductor and ground conductor configurations.
In another aspect of the invention, a method for forming an antenna comprises: providing the volumetrically configurable monopole type antenna described above, connecting the antenna to a host device; and bending the substrate and radiating structure thereon to configure impedance and/or frequency characteristics of the antenna. The method may further include: removing a portion of a ground plane of the host device adjacent to a feed of the antenna radiator.
Although the present invention has been described with reference to the foregoing preferred embodiments, it will be understood that the invention is not limited to the details thereof. Various equivalent variations and modifications can still occur to those skilled in this art in view of the teachings of the present invention. Thus, all such variations and equivalent modifications are also embraced within the scope of the invention as defined in the appended claims.
