Patent Grant
8674891
The disclosure of the above application is incorporated by reference as part of the disclosure of this document.
This document relates to Composite Right/Left Handed (CRLH) Metamaterial (MTM) antenna apparatus.
The propagation of electromagnetic waves in most materials obeys the right-hand rule for the (E, H, β) vector fields, which denotes the electrical field E, the magnetic field H, and the wave vector β (or propagation constant). The phase velocity direction is the same as the direction of the signal energy propagation (group velocity) and the refractive index is a positive number. Such materials are Right/Handed (RH) materials. Most natural materials are RH materials; artificial materials can also be RH materials.
A metamaterial (MTM) is an artificial structure. When designed with a structural average unit cell size of ρ much smaller than the wavelength of the electromagnetic energy guided by the metamaterial, the metamaterial behaves like a homogeneous medium to the guided electromagnetic energy. Unlike RH materials, a metamaterial may exhibit a negative refractive index, wherein the phase velocity direction is opposite to the direction of the signal energy propagation where the relative directions of the (E, H, β) vector fields follow a left-hand rule. Metamaterials that support only a negative index of refraction with permittivity ∈ and permeability μ being simultaneously negative are pure Left Handed (LH) metamaterials.
Many metamaterials are mixtures of LH metamaterials and RH materials and thus are CRLH metamaterials. A CRLH MTM can behave like an LH metamaterial at low frequencies and an RH material at high frequencies. Implementations and properties of various CRLH MTMs are described in, for example, Caloz and Itoh, “Electromagnetic Metamaterials: Transmission Line Theory and Microwave Applications,” John Wiley & Sons (2006). CRLH MTMs and their applications in antennas are described by Tatsuo Itoh in “Invited paper: Prospects for Metamaterials,” Electronics Letters, Vol. 40, No. 16 (August, 2004).
CRLH MTMs can be structured and engineered to exhibit electromagnetic properties that are tailored for specific applications and can be used in applications where it may be difficult, impractical or infeasible to use other materials. In addition, CRLH MTMs may be used to develop new applications and to construct new devices that may not be possible with RH materials.
This document discloses, among others, examples of apparatus and techniques that provide tuning elements in antenna devices to tune frequencies of the antenna devices, including CRLH MTM antenna devices.
The following presents examples of techniques and CRLH MTM antenna devices that provide tuning elements to tune the frequencies of the antenna devices. Examples of different types of the tuning elements include feed line tuning elements, cell patch tuning elements, meandered stub tuning elements, via line tuning elements, and via pad tuning elements that are formed near corresponding antenna elements such as the feed line, cell patch, meander stub, via line and via pad, respectively. In some implementations, a CRLH MTM antenna device can include tuning elements of one type of tuning element or tuning elements of two or more different types of tuning elements.
In one aspect, a method is provided for tuning a resonant frequency of a CRLH MTM antenna device. This method includes providing a CRLH MTM antenna on a substrate, the CRLH MTM antenna comprising antenna elements that are structured and electromagnetically coupled to one another to form a CRLH MTM structure, and providing a plurality of conductive tuning elements that are separated from one another and from the CRLH MTM antenna, and that are formed at selected locations close to the CRLH MTM antenna. One or more conductive tuning elements located next to respective antenna elements are selected to connect the selected one or more conductive tuning elements to at least one of the respective antenna elements to make the selected one or more conductive tuning elements as part of the CRLH MTM antenna to tune a resonant frequency of the CRLH MTM antenna to be different from an initial value of the resonant frequency when the selected one or more conductive tuning elements are not connected.
In another aspect, a CRLH MTM antenna device is provided to include a CRLH MTM antenna on a substrate which includes antenna elements that are structured and electromagnetically coupled to one another to form a CRLH MTM structure. Electrically conductive tuning elements are provided on the substrate and are separated from one another and from the CRLH MTM antenna. The tuning elements are formed at selected locations close to the CRLH MTM antenna and are configured to allow tuning of a resonant frequency of the CRLH MTM antenna, when one or more of the electrically conductive tuning elements located next to respective antenna elements are connected to, or disconnected from, at least one of the respective antenna elements.
In another aspect, a metamaterial antenna device is provided to include a substrate, electrically conductive parts formed on the substrate, and tuning elements formed on the substrate. The electrically conductive parts are configured to form a CRLH MTM antenna structure that generates a first plurality of frequency resonances when none of the tuning elements is connected to any of the electrically conductive parts. One or more of the tuning elements, when electrically connected to the conductive parts, reconfigure the CRLH MTM antenna structure to generate a second plurality of frequency resonances different from the first plurality of frequency resonances.
In another aspect, a method is provided for tuning a metamaterial antenna device. This method includes providing a substrate for the metamaterial antenna device, forming a plurality of conductive parts on the substrate to form a CRLH MTM antenna structure that generates a first plurality of frequency resonances, forming a plurality of tuning elements on the substrate; and connecting one or more of the tuning elements to the conductive parts to reconfigure the CRLH MTM antenna structure in a way that generates a second plurality of frequency resonances.
In yet another aspect, a method is provided for tuning a resonant frequency of a CRLH MTM antenna device by changing one or more connections of permanently-formed components of the device. This method includes providing permanently-formed antenna components on a substrate that include permanently-formed conductive antenna elements on a substrate which are structured and electromagnetically coupled to one another to form a CRLH MTM structure, and permanently-formed electrically conductive tuning elements that are positioned at different locations from one another and from the permanently-formed antenna elements and are adjacent to respective permanently-formed conductive antenna elements. In this method, one or more permanently-formed electrically conductive tuning elements located next to respective permanently-formed antenna elements are selected to connect to at least one of the respective permanently-formed antenna elements to make the selected one or more permanently-formed electrically conductive tuning elements as part of the CRLH MTM antenna to tune a resonant frequency of the CRLH MTM antenna to be different from a value of the resonant frequency when the selected one or more permanently-formed electrically conductive tuning elements are not connected.
These and other aspects and associated techniques, devices and applications are described in greater detail in the drawings, and the description and the claims below.
CRLH MTMs can be structured and engineered to exhibit electromagnetic properties that are tailored for specific applications and can be used in applications where it may be difficult, impractical or infeasible to use other materials. In addition, CRLH MTMs may be used to develop new applications and to construct new devices that may not be possible with RH materials.
Various elements of a CRLH MTM antenna device can be constructed by using a substrate with a single metal layer or with multiple metallization layers. An antenna structure can be configured to include one or more CRLH unit cells that are fed by a feed line. The CRLH unit cell includes a cell patch that is connected to a ground plane through a via line. Additionally, for multiple metallization layers, a via can be included to connect the cell patch and the via line. The feed line guides a signal to or from the cell patch and can be, for example, connected to a coplanar waveguide (CPW) feed which serves as an impedance matching device and delivers power from a signal source to the distal end of the feed line. A narrow gap is provided between the distal end of the feed line and the cell patch to electromagnetically couple these elements. For example, in one embodiment, the width of the gap is 4-8 mils. The resonant frequencies, the matching of multiple modes, and the associated efficiencies can be controlled by changing various parameters such as the size of the cell patch, the length of the via line, the length of the feed line, the distance between the antenna element and the ground, and various other dimensions and layouts.
Unlike conventional antennas, the metamaterial antenna resonances are affected by the presence of a left handed (LH) mode. In general, the LH mode helps excite and better match the low resonances and can improve the matching at high resonances.
CRLH MTM antenna structures, as discussed in this document, include one or more permanently-formed conductive antenna elements on a substrate which are structured and electromagnetically coupled to one another to form a CRLH MTM structure. Other structures include permanently-formed electrically conductive tuning elements that are positioned at different locations from one another and from the permanently-formed antenna elements and are adjacent to respective permanently-formed conductive antenna elements to tune the resonant frequencies. In a post fabricated antenna device, these permanently-formed tuning elements can be modified using removable elements, such as zero ohm resistors, to provide flexibility to meet frequency requirements. Examples of these permanently-formed tuning elements include one or more tuning elements to tune the resonant frequencies. In the absence of such tuning elements, once an antenna is printed on a Printed Circuit Board (PCB), tuning of the resonant frequencies may require changes of the PCB hardware, e.g., rebuilding the PCB, remounting components and retesting the remounted components. The present technique utilizes the tuning elements and eliminates these costly and lengthy steps; and therefore the antenna can be tuned and matched to target bands after the antenna structure is formed on the PCB. Fine tuning of the antenna design, prototyping, repair and other processes that can occur after the antenna is printed on the PCB can be simplified by using these tuning elements.
More specifically, one or more of tuning elements in the examples in this document may be coupled to corresponding antenna elements by a connecting element which conducts electricity, such as a zero-ohm resistor or zero-ohm link that acts as a bridge, between the tuning element and the corresponding antenna element. The resonant frequencies can be increased or decreased without affecting their intrinsic efficiencies by using connecting elements to manipulate connections between the tuning elements and the corresponding antenna elements.
Hence, after the PCB device with printed antenna elements and tuning elements are fabricated and completed, a resonant frequency for an antenna can be tuned by connecting one or more of the unconnected tuning elements to the antenna or disconnecting one or more of the connected tuning elements from the antenna. This tuning technique based on pre-formed tuning elements provides tuning in frequency by changing only the connections of the tuning elements without requiring changing other circuit elements formed on the PCB or rebuilding the PCB.
In some implementations of metamaterial antennas with tuning elements, various circuit parameters that can be controlled to effectuate the desired tuning include. Examples of controllable parameters are shown in Table 1.0:
In tunable metamaterial antenna devices according to some embodiments, resonant frequencies, matching of multiple modes, and associated efficiencies can be controlled by changing the size, length and/or shape of each element of the metamaterial antenna structure as well as layouts among different elements. Some examples of possible variations of the CRLH metamaterial antenna structure are illustrated in Table 2.0:
Any combination of the above, as well as other variations, may be implemented in an metamaterial antenna device.
These CRLH MTM antenna structures can be fabricated by using a conventional FR-4 substrate or a Flexible Printed Circuit (FPC) board. Examples of other fabrication techniques include thin film fabrication technique, System On Chip (SOC) technique, Low Temperature Co-fired Ceramic (LTCC) technique, and Monolithic Microwave Integrated Circuit (MMIC) technique.
In some implementations of antenna structures, a grounded CPW is used to deliver power to the feed line. Other schemes to feed the antenna include the use of a conventional CPW line without a ground plane on a different layer, a probed patch, a cable directly launched to the beginning of the feed line, or different types of Radio Frequency (RF) feed lines.
A summary of individual element parts of Antenna 1 is provided in the Table 3.0 shown below.
In an alternative configuration, the via line 223 on the top layer 233 may be directly connected to the cell patch 205 without the via. In yet another variation, the via line 223 on a third layer (not shown) may be connected to the cell patch 205 through a via formed between the bottom layer 235 and the third layer. The top and bottom layers 233, 235 as well as the additional third layer can be interchangeable in Antenna 1.
Examples of design parameter values used for implementing Antenna 1 are provided in Table 4.0 below.
A metamaterial antenna structure may be implemented based on the above design parameter values to generate efficient radiating modes in the 800 MHz to 900 MHz bands and around 2 GHz, which are used in wireless networks and services for cell phones and other applications.
Antenna 1 may have two frequency resonances in the low frequency band as can be seen from the measured return loss in
A summary of individual elements of Antenna 2 is provided in the Table 5.0 shown below.
In various implementations, some examples for the parameter values of the tuning elements in Antenna 2 are listed in Table 6.0 shown below:
Antenna 2 can be implemented to have the same two frequency bands as Antenna 1. The two frequency bands for Antenna 2 have the same three resonances as those in Antenna 1, as evidenced by the measured return loss in
Different type tuning elements for tuning metamaterial antenna structures can be implemented and some examples include feed line tuning elements, cell patch tuning elements, meandered stub tuning elements, via line tuning elements, and via pad tuning elements. In a particular metamaterial antenna structure, any one or a combination two or more of different types of tuning elements can be used to achieve the desired tuning and antenna characteristics. Tuning elements may be tuned by utilizing a conductive connector to change the physical characteristics associated with each tuning element. Such changes in physical characteristics in turn impact resonant frequencies and efficiencies in the low and high bands.
Feed Line Tuning Elements
Feed line tuning elements can be located close to the distal end of the feed line of Antenna 2. When connected by connecting elements, such as zero ohm resistors acting as bridges, feed line tuning elements can be used to effectively change the length of the feed line. In the example above, the RH resonance near 2 GHz in the high band is due to the monopole mode, which is controlled by the length of the feed line. Therefore, the feed line tuning elements provide means for tuning the resonant frequency of the RH monopole mode resonance in the high band.
Cell Patch Tuning Elements
Cell patch tuning elements can be located close to one end of the cell patch of Antenna 2. When connected by connecting elements such as zero ohm resistors acting as bridges, cell patch tuning elements can be used to effectively change the size, shape and dimensions of the cell patch. As mentioned earlier, the LH resonance in the low band is controlled by the layout and shape of the cell patch among other factors. Therefore, the cell patch tuning elements provide means for tuning the resonant frequency of the LH mode resonance in the low band.
Meandered Stub Tuning Elements
Meander stub tuning elements can be located close to the first turn of the meander stub of Antenna 2. When connected by connecting elements such as zero ohm resistors acting as bridges, meander stub tuning elements can be used to effectively change the length of the meander line. As mentioned earlier, the second resonance in the low band is an RH resonance and is controlled by the length of the meandered stub stemming from the feed line. Therefore, the meander stub tuning elements provide means for tuning the resonant frequency of the RH meander mode resonance in the low band.
Via Line Tuning Elements
Via line tuning elements can be located close to the proximal end of the via line of Antenna 2. When connected by connecting elements such as zero ohm resistors acting as bridges, via line tuning elements can be used to effectively change the length of the via line. As mentioned earlier, one of the factors determining the LH resonance in the low band is the length of the via line stemming from the bottom ground. Therefore, the via line tuning elements provide means for tuning the resonant frequency of the LH mode resonance in the low band.
Via Pad Tuning Elements
Similar to the via line tuning elements, via pad tuning elements can be used to change the overall length of the via line, and hence to tune the LH mode resonance in the low band.
Disconnecting one or more selected connecting elements in Antenna 3 can be used as a quick and efficient means for tuning and allowing for a reproducible design at each disconnected point. Like the previous case, the return loss and efficiency for Antenna 3 are the same as in the case of Antenna 2.
In another configuration of Antenna 3, certain tunable elements can be connected while other tunable elements are floating, or disconnected from other elements, as shown in
The tuning methods and structures described in this document may also be used in multi-cell designs, multilayer metamaterial designs, non-planar metamaterial structures, and other metamaterial related antenna designs.
Multi-cell designs, for example, are described in U.S. patent application Ser. No. 12/408,642 filed on Apr. 2, 2009 and entitled “Single-Feed Multi-Cell Metamaterial Antenna Devices”. In a multi-cell design, two cells may be formed in a substrate with two opposing surfaces. A top layer of a Single-Feed Multi-Cell metamaterial antenna structure comprises a first cell conductive patch of a first cell formed on the first surface; a second cell conductive patch of a second cell formed on the first surface and adjacent to the first cell conductive patch by an insulation cell gap; and a shared conductive launch stub formed on the first surface adjacent to both the first and second cell conductive patches and separated from each of the first and second cell conductive patches by a capacitive coupling gap for the first cell and a capacitive coupling gap for the second cell, respectively, which are electromagnetically coupled to each of the first and second cell conductive patches. The shared conductive launch stub includes an extended strip line that directs and receives signals from the first and second cell conductive patches. A top ground conductive electrode is formed on the first surface and spaced away from the first and second cell conductive patches. In this example, the top ground conductive electrode is patterned to include a grounded co-planar waveguide (CPW) that has a first terminal and a second terminal in which the second terminal is connected to a feed line. The shared conductive launch stub has an extended strip line that is connected to the feed line to conduct signals to or from the two cell conductive patches.
The multi-cell design may be implemented in various configurations. For example, the launch stub can have different geometrical shapes such as, but not limited to, rectangular, spiral (circular, oval, rectangular, and other shapes), or meander shapes; the MTM cell patch can have different geometrical shapes such as, but not limited to, rectangular, spiral (circular, oval, rectangular, and other shapes), or meander shapes; the via pads can have different geometrical shapes and sizes such as, but not limited to, rectangular, circular, oval, polygonal, or irregular shapes; and the gap between the launch stub and the MTM cell patch can take different forms such as, but not limited to, a straight line shape, a curved shape, an L-shape, a meander shape, a zigzag shape, or a discontinued line shape. The via trace that connects the MTM cell to the GND may be located on the top or bottom layer in some implementations.
In a multi-cell design, tuning elements described in this document such as the feed line tuning elements, cell patch tuning elements, meandered stub tuning elements, via line tuning elements, and via pad tuning elements tuning elements may be formed near corresponding structural elements such as the feed line, cell patch, meander stub, via line and via pad, respectively. Each tuning element may utilize a conductive connector element that can be either connected or disconnected to other conductive connector elements to change the physical characteristics associated with each tuning element. Such changes in physical characteristics in turn affect resonant frequencies and efficiencies in the low and high bands.
In another implementation, tuning elements in this document can be used in two or more metallization layers in metamaterial antenna structures. Examples of suitable metamaterial structures having two or more metallization layers are metamaterial structures described herein and other metamaterial structures. For example, multilayer metallization metamaterial structures described in U.S. patent application Ser. No. 12/270,410 filed on Nov. 13, 2008 and entitled “Metamaterial Structures with Multilayer Metallization and Via” can be used to implement several tuning elements previously presented. The entire disclosure of the application Ser. No. 12/270,410 is incorporated by reference as part of the disclosure of this document.
application Ser. No. 12/270,410 discloses techniques and apparatus based on metamaterial structures for antenna and transmission line devices, including multilayer metallization metamaterial structures with one or more conductive vias connecting conductive parts in two different metallization layers. In one aspect, a metamaterial device is provided to include a substrate, a plurality of metallization layers associated with the substrate and patterned to have a plurality of conductive parts, and a conductive via formed in the substrate to connect a conductive part in one metallization layer to a conductive part in another metallization layer. The conductive parts and the conductive via form a composite right and left handed (CRLH) metamaterial structure. In one implementation of the device, the conductive parts and the conductive via of the CRLH MTM structure are structured to form a metamaterial antenna and are configured to generate two or more frequency resonances. In another implementation, two or more frequency resonances of the CRLH MTM structure are sufficiently close to produce a wide band. In another implementation, the parts and the conductive via of the CRLH MTM structure are configured to generate a first frequency resonance in a low band and a second frequency resonance in a high band, the first frequency resonance being a left-handed (LH) mode frequency resonance and the second frequency resonance being a right-handed (RH) mode frequency resonance. In yet another implementation, the parts and the conductive via of the CRLH MTM structure are configured to generate a first frequency resonance in a low band, a second frequency resonance in a high band, and a third frequency resonance which is substantially close in frequency to the first frequency resonance to be coupled with the first frequency resonance, providing a combined mode resonance band that is wider than the low band.
In another aspect disclosed in application Ser. No. 12/270,410, a metamaterial device is provided to include a substrate, a first metallization layer formed on a first surface of the substrate and patterned to comprise a cell patch and a launch pad that are separated from each other and are electromagnetically coupled to each other, and a second metallization layer formed on a second surface of the substrate parallel to the first surface and patterned to comprise a ground electrode located outside a footprint of the cell patch, a cell via pad located underneath the cell patch, a cell via line connecting the ground electrode to the cell via pad, an interconnect pad located underneath the launch pad, and a feed line connected to the interconnect pad. This device also includes a cell via formed in the substrate to connect the cell patch to the cell via pad and an interconnect via formed in the substrate to connect the launch pad to the interconnect pad. One of the cell patch and the launch pad is shaped to include an opening and the other of the cell patch and the launch pad is located inside the opening. The cell patch, the cell via, the cell via pad, the cell via line, the ground electrode, the launch pad, the interconnect via, the interconnect via and the feed line form a CRLH MTM structure. In another aspect, a wireless communication device includes a printed circuit board (PCB) comprising a portion that is structured to form an antenna. The antenna includes a CRLH MTM cell comprising a top metal patch on a first surface of the PCB, a bottom metal pad on a second, opposing surface of the PCB and a conductive via connecting the top metal patch and the bottom metal pad; and a grounded co-planar waveguide (CPW) formed on the top surface of the PCB at a location to be spaced from the CRLH metal material cell and comprising a planar waveguide (CPW) feed line, a top ground (GND) around the CPW feed line. The CPW feed line has a terminal located close to and capacitively coupled to the top metal patch of the CRLH MTM cell. The antenna also includes a bottom ground metal patch formed on the bottom surface of the PCB below the grounded CPW formed on the top surface of the PCB; and a bottom conductive path that connects the bottom ground metal path to the bottom metal pad of the CRLH MTM cell. In one implementation, the antenna is configured to have two or more resonances in different frequency bands, which may, for example, include a cellular band from 890 MHz to 960 MHz and a PCS band from 1700 MHz to 2100 MHz. In yet another aspect, a wireless communication device includes a printed circuit board (PCB) comprising a portion that is structured to form an antenna. This antenna includes a CRLH MTM cell comprising a top metal patch on a first surface of the PCB; a grounded co-planar waveguide (CPW) formed on the top surface of the PCB at a location to be spaced from the CRLH metal material cell and comprising a planar waveguide (CPW) feed line, a top ground (GND) around the CPW feed line, wherein the CPW feed line has a terminal located close to and capacitively coupled to the top metal patch of the CRLH MTM cell; and a top ground metal path formed on the top surface of the PCB to connect to the top ground and the top metal patch of the CRLH MTM cell. In one implementation, the antenna is configured to have two or more resonances in different frequency bands, which may, for example, include a cellular band from 890 MHz to 960 MHz and a PCS band from 1700 MHz to 2100 MHz.
In a multilayer design, tuning elements such as the feed line tuning elements, cell patch tuning elements, meandered stub tuning elements, via line tuning elements, and via pad tuning elements tuning elements may be formed near corresponding structural elements such as the feed line, cell patch, meander stub, via line and via pad, respectively. Each tuning element may utilize an electrically conductive connector element that can be either connected or disconnected to other conductive connector elements to change the physical characteristics associated with each tuning element. Such changes in physical characteristics in turn affect resonant frequencies and efficiencies in the low and high bands.
In addition, the tuning elements in this document can be implemented in non-planar metamaterial configurations. Such non-planar metamaterial antenna structures arrange one or more antenna sections of an metamaterial antenna away from one or more other antenna sections of the same metamaterial antenna so that the antenna sections of the metamaterial antenna are spatially distributed in a non-planar configuration to provide a compact structure adapted to fit to an allocated space or volume of a wireless communication device, such as a portable wireless communication device. For example, one or more antenna sections of the metamaterial antenna can be located on a dielectric substrate while placing one or more other antenna sections of the metamaterial antenna on another dielectric substrate so that the antenna sections of the metamaterial antenna are spatially distributed in a non-planar configuration such as an L-shaped antenna configuration. In various applications, antenna portions of a metamaterial antenna can be arranged to accommodate various parts in parallel or non-parallel layers in a three-dimensional (3D) substrate structure. Such non-planar metamaterial antenna structures may be wrapped inside or around a product enclosure. The antenna sections in a non-planar metamaterial antenna structure can be arranged to engage to an enclosure, housing walls, an antenna carrier, or other packaging structures to save space. In some implementations, at least one antenna section of the non-planar metamaterial antenna structure is placed substantially parallel with and in proximity to a nearby surface of such a packaging structure, where the antenna section can be inside or outside of the packaging structure. In some other implementations, the metamaterial antenna structure can be made conformal to the internal wall of a housing of a product, the outer surface of an antenna carrier or the contour of a device package. Such non-planar metamaterial antenna structures can have a smaller footprint than that of a similar metamaterial antenna in a planar configuration and thus can be fit into a limited space available in a portable communication device such as a cellular phone. In some non-planar metamaterial antenna designs, a swivel mechanism or a sliding mechanism can be incorporated so that a portion or the whole of the metamaterial antenna can be folded or slid in to save space while unused. Additionally, stacked substrates may be used with or without a dielectric spacer to support different antenna sections of the metamaterial antenna and incorporate a mechanical and electrical contact between the stacked substrates to utilize the space above the main board.
Non-planar, 3D metamaterial antennas can be implemented in various configurations. For example, the metamaterial cell segments described herein may be arranged in non-planar, 3D configurations for implementing a design having tuning elements formed near various metamaterial structures. U.S. patent application Ser. No. 12/465,571 filed on May 13, 2009 and entitled “Non-Planar Metamaterial Antenna Structures”, for example, discloses 3D antennas structure that can implement tuning elements near metamaterial structures. The entire disclosure of the application Ser. No. 12/465,571 is incorporated by reference as part of the disclosure of this document.
In one aspect, the application Ser. No. 12/465,571 discloses an antenna device to include a device housing comprising walls forming an enclosure and a first antenna part located inside the device housing and positioned closer to a first wall than other walls, and a second antenna part. The first antenna part includes one or more first antenna components arranged in a first plane close to the first wall. The second antenna part includes one or more second antenna components arranged in a second plane different from the first plane. This device includes a joint antenna part connecting the first and second antenna parts so that the one or more first antenna components of the first antenna section and the one or more second antenna components of the second antenna part are electromagnetically coupled to form a composite right and left handed (CRLH) metamaterial (MTM) antenna supporting at least one resonance frequency in an antenna signal and having a dimension less than one half of one wavelength of the resonance frequency. In another aspect, the application Ser. No. 12/465,571 discloses an antenna device structured to engage an packaging structure. This antenna device includes a first antenna section configured to be in proximity to a first planar section of the packaging structure and the first antenna section includes a first planar substrate, and at least one first conductive part associated with the first planar substrate. A second antenna section is provided in this device and is configured to be in proximity to a second planar section of the packaging structure. The second antenna section includes a second planar substrate, and at least one second conductive part associated with the second planar substrate. This device also includes a joint antenna section connecting the first and second antenna sections. The at least one first conductive part, the at least one second conductive part and the joint antenna section collectively form a composite right and left handed (CRLH) metamaterial structure to support at least one frequency resonance in an antenna signal. In yet another aspect, the application Ser. No. 12/465,571 discloses an antenna device structured to engage to an packaging structure and including a substrate having a flexible dielectric material and two or more conductive parts associated with the substrate to form a composite right and left handed (CRLH) metamaterial structure configured to support at least one frequency resonance in an antenna signal. The CRLH MTM structure is sectioned into a first antenna section configured to be in proximity to a first planar section of the packaging structure, a second antenna section configured to be in proximity to a second planar section of the packaging structure, and a third antenna section that is formed between the first and second antenna sections and bent near a corner formed by the first and second planar sections of the packaging structure.
Non-planar, 3D metamaterial antennas can be configured to use tuning elements such as the feed line tuning elements, cell patch tuning elements, meandered stub tuning elements, via line tuning elements, and via pad tuning elements tuning elements which are connected to corresponding structural elements such as the feed line, cell patch, meander stub, via line and via pad, respectively. Each tuning element may utilize a conductive connector element that can be either connected or disconnected to other conductive connector elements to change the physical characteristics associated with each tuning element. Such changes in physical characteristics in turn affect resonant frequencies and efficiencies in the low and high bands. Furthermore, the above structures can be used to design other RF components such as but not limited to filters, power combiner and splitters, diplexers, and the like. Also, the above structures can be used to design RF front-end subsystems.
Combination of these configurations can be used to improve impedance matching and achieve high efficiency in all bands of interest.
As mentioned earlier, the tuning elements can be varied in terms of the number, location, size, shape, spacing and various other geometrical parameters depending on which resonances to tune by how much. The present tuning technique by use of the tuning elements provides practical ways to fine tune the resonant frequencies after the antenna is printed on the circuit board, thus simplifying the design, prototyping, fabrication, repair, and various other processes prior to mass production with the final design.
In the above examples the base metamaterial antenna has two layers with a via connecting two conductive parts in the different layers, a single layer via-less metamaterial antenna structure or a multilayer metamaterial antenna structure (with more than two layers) can also be implemented with the tuning elements. In the single layer via-less structure, the via pad tuning elements are not necessary.
While this document contains many specifics, these should not be construed as limitations on the scope of any invention or of what is claimed, but rather as descriptions of features specific to particular embodiments. Certain features that are described in this document in the context of separate embodiments can also be implemented in combination in a single embodiment. Conversely, various features that are described in the context of a single embodiment can also be implemented in multiple embodiments separately or in any suitable subcombination. Moreover, although features is described above as acting in certain combination can in some cases be exercised for the combination, and the claimed combination is directed to a subcombination or variation of a subcombination.
Particular implementations have been described in this document. Variations and enhancements of the described implementations and other implementations can be made based on what is described and illustrated in this document.
This patent document claims the benefits of U.S. Provisional Patent Application Ser. No. 61/116,232 entitled “TUNABLE METAMATERIAL ANTENNA STRUCTURES” and filed on Nov. 19, 2008.
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| “European Application Serial No. 09828126.4, Response filed Oct. 3, 2013 to Extended European Search Report mailed Mar. 20, 2013”, 16 pgs. |
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| Number | Date | Country | |
|---|---|---|---|
| 20100123635 A1 | May 2010 | US |
| Number | Date | Country | |
|---|---|---|---|
| 61116232 | Nov 2008 | US |
