The invention relates to metamaterials, for example to metamaterials lenses in antenna systems.
The maximum possible gain of a conventional aperture antenna is determined by the size of the aperture. Hence, dish reflectors, horn antennas, array antennas and other electrically large antennas may have large gain due to their large aperture area. However, many applications would benefit from small antenna sizes, and approaches to improving antenna gain without increasing antenna size or weight would be extremely useful for a variety of applications.
Examples of the present invention include anisotropic low-index metamaterials used as a far-field collimating lens. Example uniaxial metamaterials have low values (e.g. <1) for both ∈z and μz, producing 3D collimated beams. For a planar metamaterial lens, z is a surface normal to a lens face. A balanced response to both dipoles may be obtained by configuring the metamaterial such that ∈z=μz, ∈T=μT.
An example metamaterial uses dual-split ring resonators (DSRR) in the x-y plane for a low permeability response, and end-loaded dipole (ELD) elements in the x-z and y-z planes for a low permittivity response. As ∈z or μz approaches zero, the pass-band narrows, improving collimation and directivity of the antenna. Applications include a high-gain, low-profile circularly-polarized antenna. Apparatus according to examples of the present invention include a high-gain, low-profile circularly-polarized antenna including a metamaterial lens.
Examples of the present invention include an anisotropic low-index metamaterial used as a far-field collimating lens for an antenna feed, such as a dual-polarization crossed-dipole antenna feed. The metamaterial may be uniaxial, having low values for both ∈z and μz that produce 3D collimated beams. An example method of improving the directivity of an antenna, in particular a circularly polarized antenna, includes passing radiation transmitted or received by the antenna through a metamaterial lens according to an example of the present invention.
Example apparatus include a metamaterial, such as a planar metamaterial which may be used as a lens. Split-ring resonators are disposed in a first plane, and end-loaded dipoles are disposed in at least one plane perpendicular to the first plane. A uniaxial planar metamaterial include split-ring resonators disposed in a first plane parallel to the faces of the planar metamaterial, and end-loaded dipoles disposed in two perpendicular planes including a surface normal. The split-ring resonators may be configured to give a low permeability, and may be dual-split ring resonators. The end-loaded dipoles may be configured to give a low permittivity.
An example planar metamaterial extending within a metamaterial plane includes an array of dual-split ring resonators (DSRR) in the metamaterial plane (parallel to the lens face, denoted the x-y plane in some examples below), and end-loaded dipoles disposed in the x-z plane and/or the y-z plane, perpendicular to the x-y plane, where z is a surface normal. The metamaterial may include an arrangement, such as a lattice, of planar dielectric substrates. The metamaterial may be uniaxial, the axis of uniaxiality being parallel to the surface normal (z-direction). For a slab lens having planar faces, the z-direction is perpendicular to the lens faces. A dielectric substrate may be a generally planar rigid dielectric sheet, such as those used for printed circuit boards, including high frequency laminates.
Example apparatus include an antenna, for transmission and/or reception of radiation, including the planar metamaterial and an antenna feed, the planar metamaterial being a metamaterial lens for the antenna feed. The antenna feed may be a dual-polarization crossed-dipole antenna feed, and the antenna may be a circularly polarized antenna.
An example metamaterial has values of both ∈z and μz that are both less than 1, ∈z being a permittivity along a z-direction normal to the input and output faces of the planar metamaterial, and μz being a permeability along the z-direction. The metamaterial may be anisotropic, such as uniaxial. Here, μz be obtained using a resonant structure including a ring resonator, such as a dual-split ring resonator. Also, ∈z may be obtained using a resonant structure including an end-loaded dipole.
A novel metamaterial may comprise a repeated unit cell structure, the unit cell structure including an end-loaded dipole. An end-loaded dipole (ELD) may be used to realize a low permittivity electrically active material, and providing four vertical ELD elements on adjacent sides of a cube/cuboid unit cell creates a volumetric ELD (VELD), useful for producing a uniaxial permittivity. A cubic metamaterial unit cell may comprise two split-ring resonators (on upper and lower faces) and four ELD structures arranged as a VELD. A metamaterial according to an example of the present invention includes a plurality of VELDs, for example formed by orthogonal intersecting arrays of ELDs. Split ring resonators and ELDs may be formed by etching a metal-coated dielectric substrate, for example using printed circuit board techniques.
Example apparatus include a metamaterial lens having an operating frequency, having parallel and spaced apart lens faces, the metamaterial including split-ring resonators disposed parallel to the lens faces, and end-loaded dipoles disposed in at least one plane perpendicular to the lens faces. An example metamaterial lens is a slab lens, having first and second planar faces, spaced apart by the lens thickness, and having length side lengths that may or may not be equal, so the lens may have square or rectangular faces. The lens side lengths are greater than the lens width. The lens faces may be provided by dielectric substrates used to support arrays of split ring resonators. There may optionally be one or more additional dielectric substrate located between the lens faces, also used to support arrays of split-ring resonators, the dielectric layers used to support split ring resonators being spaced apart and parallel. The split-ring resonators may dual-split ring resonators, having two gaps in a conducting loop. Further dielectric substrate are used to support arrays of end-loaded dipoles (ELDs), and these substrates are arranged in a three-dimensional intersecting pattern. One group of dielectric substrates is used to support the ELDs are arranged perpendicular to the lens faces, and may be parallel to the first edge of a slab lens. Another group of dielectric substrates supporting ELDs, are arranged intersecting the first group, and also perpendicular to the lens faces. The lens may be a microwave lens, radar lens, or other electromagnetic lens.
An end-loaded dipole may include a conducting track, such as a linear conducting portion having a first end and a second end, a first sinuous end-loading arm electrically connected to the first end, and a second sinuous end-loading arm electrically connected to the second end. The linear portion and sinuous end-loading arms may be formed as a single uninterrupted conducting track.
End-loaded dipoles may be configured to have a permittivity of less than 1 at the operating frequency of the lens, i.e. for electromagnetic radiation having the operating frequency. The split ring resonators and end-loaded dipoles are configured so that the metamaterial lens has a permittivity ∈z and a permeability μz at the operating frequency, where μz is the permeability along a direction normal to the lens faces, ∈z is the permittivity along a direction normal to the lens faces, and ∈z and μz are both less than 1, such as between 0 and 1 (inclusive), for example between 0 and 0.5, and in some examples between 0 and 0.3.
A repeated cubic structure (such as a unit cell) of the metamaterial, or cube formed by intersecting dielectric substrates, may include split-ring resonators (such as a DSRR) on a pair of opposed faces of the cubes, and ELDs on the remaining four faces of the cube. Such an arrangement of ELDs may be referred to as a volumetric ELD, or VELD. The apparatus of claim 1, the apparatus comprising a three-dimensional arrangement of dielectric substrates supporting the split-ring resonators and the end-loaded dipoles, the split-ring resonators and the end-loaded dipoles being conducting patterns formed on the dielectric substrates. A three-dimensional arrangement of dielectric substrates may a plurality of hollow dielectric cubes, a dielectric cube supporting a pair of split ring resonators on opposed faces of the dielectric cube, and end-loaded dipoles on the remaining faces of the dielectric cube. The split ring resonators and end-loaded dipoles may be supported on the interior and/or exterior surfaces of the dielectric cube.
The operating frequency of the lens may be in the range 1 GHz-100 GHz, in some examples in the range 1 GHz-20 GHz. In some examples, the lens is used as a lens for microwave radiation. The metamaterial lens may be used in a radar apparatus at any frequency conventionally used for radar, including low frequency radar applications. Example apparatus include radar, wireless communication, microwave, or other electromagnetic apparatus such as transmitters and/or receivers including a metamaterial lens. The lens may have a pair of lens faces, for example as input face and an output face of the lens, and the lens faces may be planar, spaced apart, and parallel to each other. An example metamaterial lens includes arrays of dual-split ring resonators, supported by dielectric substrates disposed parallel to the lens faces. Each substrate may support an array of resonators on one or both sides of the substrate. Arrays of end-loaded dipoles are supported by dielectric substrates disposed perpendicular to the lens faces, and also on dielectric substrates disposed perpendicular to both the first and second dielectric substrates.
An example antenna, which may be used to transmit and/or receive electromagnetic radiation includes a ground plane, typically a highly electrically conducting sheet such as a metal sheet, and an antenna feed, such as a dipole, combination of dipoles, or other radiative or receptive element. The ground plane is spaced apart from and parallel to the metamaterial lens, the antenna feed being located between the ground plane and the metamaterial lens. Example lenses appreciably improve the directionality of the antenna. The antenna feed may be a dual-polarization crossed-dipole antenna feed, for example producing circularly polarized radiation. The lens may be configured to have collimating properties independent of rotational of the lens in the plane of the lens face plane.
Examples of the present invention include metamaterials, including metamaterial lenses having material properties that approximate the behavior of a material with low effective index of refraction n (e.g. 0≦n≦1). Metamaterials may be designed and tuned using dispersion engineering to create a relatively wide-band low-index metamaterial lens, where permittivity and permeability normal to the lens face are less than 1, for example in the range 0-1, inclusive. The term meta-lens is sometimes used as an abbreviation for metamaterial lens, and LIM is sometimes used as an abbreviation for a low index lens. In some examples, the permittivity and permeability normal to the lens face are approximately zero, giving a zero-index metamaterial (ZIM) lens configuration.
An example metamaterial uses dual-split ring resonators (DSRR) in the x-y plane for a low permeability response, and end-loaded dipole (ELD) elements in the x-z and y-z planes for a low permittivity response. As ∈z or μz approaches zero, the pass-band narrows, improving collimation and directivity of the antenna, as shown by full-wave electromagnetic simulations and experimental data. A metamaterial lens using these resonators created highly collimated beams in the far-field, from a low-directivity antenna feed such as a dipole. Example metamaterials were configured for use with microwave radiation, but can be scaled to other frequencies of interest, such as radar frequencies.
Examples of the present invention include collimating lenses including low-index metamaterials (LIMs). A collimating lens, including a thin square slab of uniaxial low-index metamaterial, may be used with a circularly-polarized crossed-dipole antenna feed situated proximate a metallic ground plane, between the lens and the ground plane. The combination of magnetic and electric low-index properties allows far-field collimation of circularly-polarized radiation.
Polarization-independent collimating metamaterial lenses (meta-lenses) were designed, simulated, and successfully fabricated using PCB techniques. Experimental data and simulations both indicated excellent lens performance over a ˜10% impedance bandwidth and ˜15% pattern bandwidth. A metamaterial lens with equal uniaxial permittivity and permeability can be used with linearly polarized dipole or circularly polarized crossed-dipole antenna feeds. Example metamaterials were designed using both magnetic split-ring resonators (SRRs) and electric end-loaded dipoles (ELDs), combined to produce the desired matched magneto-electric response.
An example metamaterial lens was constructed using PCB technology and the measured radiation patterns showed good agreement with simulated design data for the lens. Increasing the gain and effective aperture size with the lens allows the use of smaller, lighter antenna feeds while obtaining excellent radiation characteristics. Example low-index lens metamaterial designs are compact and light, and suitable for space and aerospace applications, for example by replacing reflector antennas. A meta-lens design only requires a single feed, and is inexpensive and low-loss compared to conventional array beamforming systems. Examples also include lens and feed pairs with wider impedance bandwidth, and metamaterials with multi-band operation.
Gain enhancement may be achieved using dielectric lenses, antenna arrays, reflector dishes, volumetric and endfire elements, or by increasing the antenna size. However, these approaches generally result in large, bulky, and heavy apparatus. Previous metamaterial and EBG lenses have low operational bandwidth, and may be highly polarization-sensitive. Array antennas have relatively high manufacturing cost, complexity, and high loss. Examples of the present invention allow these problems to be avoided.
Using a thin ZIM/LIM slab lens to spread and collimate the energy from a low-directivity antenna feed increases the effective aperture size of the system, which can fit within a smaller volume than would be required for a more traditional dish antenna for example. A thin slab ZIM can be used as a directivity-enhancing superstrate or lens, the thin lens producing highly-directive radiation while allowing the use of low-cost antennas with simple feed and impedance-matching networks compared to conventional antenna arrays. In this context, a thin lens has a thickness less than the operational wavelength. Example apparatus may be designed for use in space, for example configured for use on a satellite.
The gain of an antenna over an isotropic source is a key metric in the design of a communication system. The maximum gain of a non-volumetric antenna is related to the size of the aperture. Dish reflectors and other electrically large antennas will have large gain due to their large aperture area. For many applications, it is advantageous to obtain increased gain without increasing aperture.
Example apparatus include wideband, resonant metamaterials with operation over 12% bandwidth at 8 GHz, much wider than the 1-3% achieved by earlier metamaterial designs. Hence, example lenses may have a bandwidth of over 10% of the nominal operational frequency. Example metamaterials are light and compact, for example using a hollow printed circuit board (PCB) construction or other dielectric substrate.
Examples include an anisotropic low-index metamaterial configured as a far-field collimating lens, which may be used with a dual-polarization crossed-dipole antenna feed. A balanced response to both dipoles may be obtained using ∈z=μz, ∈T=μT. Example metamaterials are uniaxial, and have low values for both ∈z and μz that produce 3D collimated beams. Example metamaterials use dual-split ring resonators (DSRR) in the x-y plane for a low permeability response (<1, such as ≦0.5, e.g. ≦0.2, and ≧0), and end-loaded dipole (ELD) elements in the x-z and y-z planes for a low permittivity response (<1, such as ≦0.5, e.g. ≦0.2, and ≧0). As ∈z or μz approaches zero, the pass-band narrows, improving collimation and directivity of the antenna.
Examples of the present invention also include high-gain, low-profile circularly-polarized antennas. Example lenses may be configured to be polarization-insensitive, allowing use in systems that broadcast or receive circularly-polarized transmissions, or for multiplexing multiple data streams onto the same frequency channel. These compact, broadband, polarization-insensitive metamaterials are an important development in the fields of antenna design and communications, in particular space-based communications.
Example apparatus include one or more antennas, such as monopole antennas, embedded in or otherwise proximate to a zero-index or low-index metamaterial. The metamaterial may be a planar metamaterial of one or more layers, and may comprise one or more dielectric substrates. In some examples, conducting elements may be partially or wholly self-supporting. An anisotropic metamaterial may be used to enhance the directivity of directed radiation Metamaterials may also be used as a as superstrate or metamaterial lens for the antenna.
Examples of the present invention include fully 3D anisotropic metamaterials that uses both horizontal and vertical metamaterial elements. A metamaterial may be a generally planar structure, for example as a two-dimensional repeated array of unit cell structures. The unit cell dimensions may be small compared to the operational wavelength, for example λ/5 or less. The metamaterial may be configured so that there is a good impedance match to the antenna, greatly reducing the reflected energy.
Examples of the present invention include an anisotropic low-index metamaterial structure for a far-field collimating lens, which may be used in conjunction with an antenna feed such as a dual-polarization crossed-dipole antenna feed situated above a metallic ground plane. In some examples, a high impedance ground plane may be included located proximate (e.g. under) an antenna used to receive (and/or transmit) signals. An artificial magnetic conductor may be used to reduce antenna thickness.
Electromagnetic Properties of Metamaterial Lenses
Electromagnetic (EM) properties of anisotropic ZIMs/LIMs, and applications as thin lenses for the purpose of antenna directivity enhancement (beam collimation) are now examined. The lens design process assumes homogeneous materials. A metamaterial is selected to approximate the homogenous structure, and the fabrication and measurement of a prototype device allows comparison with the predicted results. A proposed meta-lens structure comprises uniaxial medium whose effective permittivity and permeability tensors have the form given in (1) below:
The material parameters for the fields along the optical axis (∈z and μz) are different from those for fields along the transverse axes (∈T=∈X=∈Y and μT=μX=μY). The meta-lens is constructed so that its interfaces are normal to the optical axis (z axis) of the uniaxial medium. As a result, the dispersion relations for TE and TM polarized wave propagation inside this medium can be described by Equation (2):
where k0 is the free space wave number. The dispersion relations are useful for determining the wave vector β inside the metamaterial, since the tangential component of the wave vector will be conserved at the interface.
In order to evaluate the collimating performance, the transmission and reflection characteristics of the meta-lens under plane wave illumination are studied. Based on the wave propagation vectors derived above, we can compute the fundamental transmission and reflection coefficients at the interface between the metamaterial and surrounding medium. For TE polarized waves obliquely incident upon the slab, the transmission and reflection coefficients (τ1 and ρ1) can be found by using (3):
In (3), kz is the normal component of the wave vector in free space, which is related to the incident angle θi by kz=k0 cos θi. Similarly, we can calculate the coefficients (τ2 and ρ2) at the back surface of the meta-lens as
Consequently, by taking into account the multiple reflections occurring at the front and back surfaces of the meta-lens, we find the transfer function as given in (5).
Since the transfer function relates the electric fields at the front and back surfaces of the metamaterial slab, this transfer function may be used to characterize the EM properties of example meta-lens.
As LIMs are needed for the construction of collimating lenses, the transfer functions of several low-index uniaxial metamaterial slabs were investigated. In all the cases, the transverse components of the permittivity and permeability tensors (∈T and μT) are unity and the thickness of the slab is 0.5λ0.
The low-index meta-lens behaves as a low-pass spatial filter for plane wave components with different transverse wave vectors. The angular passband region becomes narrower as μz approaches zero. As a result, waves propagating through such a meta-lens will be concentrated into a narrow cone with collimated propagation normal to the surface of the meta-lens. This effect can be used to enhance the directivity of an antenna that is placed underneath the meta-lens.
From the analysis of the behavior of the various low-index meta-lenses, it is apparent that the uniaxial low-index metamaterial lens exhibits superior collimation performance compared to other candidates. Electric and magnetic metamaterials with anisotropic properties can be realized using various subwavelength resonators.
A low-index metamaterial behaves as a low-pass spatial filter for different plane wave components and the pass-band becomes narrower as ∈z or μz approaches zero. As a result, waves propagating through such a metamaterial are collimated and the directivity of an antenna that is placed underneath the metamaterial is enhanced. This configuration allows design of a high-gain low-profile circularly-polarized antenna, compared to a more classical helical antenna.
Example metamaterials possesses low values for both ∈z and μz in order to produce three-dimensional collimated beams. Using a dual dipole antenna source, a balanced response to both dipoles is obtained by using matched material parameters (∈z=μz, ∈T=μT) to produce the desired circularly-polarized radiation. In order to prevent energy leakage from the sides of the lens, metal strips were placed around the outer edges of the lens. Any effectively perfect electrical conductor edge (PEC edge) may be used.
Such an anisotropic metamaterial design was found to have better matching and collimation performance compared to an isotropic counterpart. Furthermore, it can be simpler to implement an anisotropic metamaterial where only one component of the material tensor must be controlled than an isotropic metamaterial. Lenses with similar collimation capabilities have also been demonstrated through the coordinate transformation approach. However, the resulting material requirements are usually challenging to achieve in a practical metamaterial and result in limited operating bandwidth. Moreover, some TO designs can even be simplified and realized using homogeneous and anisotropic zero- or low-index metamaterials with comparable device performance.
Metamaterial Design
The design of a matched uniaxial magneto-electric metamaterial can be broken into two separate parts; one for a metamaterial with near-zero z-directed permeability and the other for a near-zero z-directed permittivity. Combining the two components will then produce a metamaterial that can be tuned to have matched and uniaxial effective parameters as required for construction of the collimating meta-lens.
In the microwave regime, printed-circuit board (PCB) fabrication can be used for metamaterial construction, where metallic structures are implemented as planar PCB traces on one or both sides of a dielectric substrate. The conducting structures of the metamaterial molecules are then modeled as infinitely thin perfectly-conducting (PEC) patches on the inside surfaces of hollow dielectric blocks.
Conventional negative index or left-handed metamaterials (NIMs) operate in the resonance region where the permittivity and permeability are simultaneously negative. In contrast, ZIM/LIM lenses according to examples of the present invention function in the high-frequency tail near the zero-crossing of the resonance, where the absorption losses are low with greater achievable bandwidth.
Magnetic Metamaterials
Split ring resonators (SRRs) may be used to manipulate the magnetic properties of metamaterial devices. An electrically conducting loop pattern, which may be formed as printed tracks on a PCB, couples strongly to the normal magnetic field and exhibits an LC resonance. A split ring resonator includes an electrically conducting loop pattern with a gap in the conducting track, sometimes called a capacitive gap. The resonance may be tuned by scaling the gap and loop dimensions. Arrays of SRR elements at resonance produce a Lorenz-Drude effective permeability response that may be used to produce devices with large, small, and negative effective permeability.
A modified split-ring resonator designed for a low-index magnetic material. An example SRR is shown in
Adding a second gap to the SRR decreases capacitance by a factor of two, scales the resonant frequency by a factor of approximately 1.4, and increases the electrical size of the resonator. The SRR is magnetically active for the normally oriented magnetic field, so the array of SRRs is aligned in the x-y plane to promote a z-permeability (μz) response. The resonant frequency and associated low-index band are controlled by modifying the capacitance or inductance of the series RLC equivalent circuit. Modifying inductance and/or capacitance through increased resonator area, decreased wire thickness, longer capacitive coupling arms, using surface-mounted components, or reducing the capacitive gap width will decrease the frequency of the LIM band.
The performance of an SRR array was evaluated by modeling a single unit cell in HFSS using periodic boundary conditions, thus simulating an infinite array of elements. The reflection (R) and transmission (T) scattering parameters are then numerically determined for the periodic slab. Assuming that the metamaterial may be treated as a thin, infinite slab of homogeneous material, the scattering coefficients can be inverted using the Fresnel equations to yield the effective permittivity (∈) and permeability (μ) parameters for the material. Since these unit cells produce diagonally anisotropic parameters, and each set of scattering parameters for a given polarization and wave incidence direction results in a single ∈/μ pair, three simulations are run to extract all six terms of the permittivity and permeability tensors. Simulations are performed for waves traveling in each of the X, Y, and Z directions through the unit cell.
Electric Metamaterial
Hence, an improved resonator configuration was designed, denoted an end-loaded dipole. Improved end-loaded dipole resonators are illustrated in
Combining four vertical (planar) ELD elements creates a 3D volumetric ELD (VELD) unit cell as shown in
Simulations of the lens composed of a homogeneous slab with material parameter dispersion taken from unit cell simulations showed that the desired collimating effect was achieved even with non-unity tangential permittivity components.
To demonstrate the collimation effects of the meta-lens, a crossed dipole antenna was placed over (proximate) a ground plane, such as a metallic sheet, and modeled as a perfectly conducting ground plane. When fed with a 90 degree phase offset, the crossed-dipole antenna generates circularly polarized radiation. As shown in
Since the radiated fields from the crossed dipoles contain both TE and TM waves, the meta-lens must possess low values for both ∈z and μz in order to produce collimated beams in both the E and H planes. A balanced response to both dipoles is obtained by using matched material parameters (∈z=μz=0.2, ∈T=μT=1) to produce the desired circularly-polarized radiation. The meta-lens is placed above the crossed dipoles with a ground plane underneath. In order to prevent energy leakage from the sides of the lens, metal strips were placed around its outer edges. These metal strips mimic graded material parameters and help guide the waves to propagate forward in the desired direction.
Notches in the ELD strips allowed the creation of a square grid with oppositely-oriented strips assembled at right-angles. To ensure accurate placement of the SRR panel, an array of holes was drilled to correspond to pegs located on the top and bottom of the ELD strips. The exterior transverse edges of the lens were secured with small quantities of epoxy, but no adhesive was used inside the lens structure to prevent changes to the metamaterial behavior. The metal features were printed on 20 mil Rogers 4003 dielectric substrate (Rogers Corp, Rogers, Conn.) with dimensions adjusted to yield a low-index metamaterial operating band from 6.5 to 7.75 GHz. A 19.6 mm coax-fed half-wave dipole antenna with a 20 mm coaxial taper balun was constructed and trimmed for resonance at 7 GHz in the free space to obtain a good impedance match.
The radiation patterns from the two lens orientations show minimal differences, indicating that the lens performs equally well for both incident linear polarizations and has excellent performance with circularly-polarized systems. Measured and simulated radiation patterns are representative of performance and simulation/measurement agreement over the entire band. The antenna has a pattern and impedance bandwidth of over 0.7 GHz (i.e. over 10% bandwidth, relative to an operational frequency in the center of the band). The minor disagreements between the measured and simulated patterns are due to small discrepancies in the manufacturing process.
The illustrated cube may be a unit cell, approximation thereof, or representative of a dielectric cube formed by dielectric sheets used as dielectric substrates. A dielectric cube may be formed by three pairs of parallel, spaced apart, dielectric substrate, each pair being perpendicular to the two other pairs. The spacing of each pair of dielectric substrates is the same, so that the intersection of the substrates forms the dielectric cubes. Each face of the cube may include a single resonator of an array of resonators.
The end-loaded dipole (ELD) illustrated in
The unit cells were tuned to achieve roughly simultaneous zero-crossings in both permittivity and permeability near 8 GHz for a low-index operational band from approximately 8 to 9 GHz. In the microwave regime, printed-circuit board (PCB) fabrication is a good solution for metamaterial construction, where metallic structures are implemented as planar PCB traces on one or both sides of a dielectric substrate. The resulting material is uniaxial for both permittivity and permeability in the desired range and satisfies the example design goal.
Table I and II below give dimensions of an example metamaterial design for use in the 8-9 GHz band. Table I shows example metamaterial unit cell parameters for a dual split-ring resonator. Table II shows example metamaterial unit cell parameters for a volumetric end-loaded dipole. These parameters are exemplary, and may be scaled for application at other frequencies.
To demonstrate the collimation performance, a 60×60×5 mm metamaterial comprising designed cubical unit cells was simulated using HFSS. A crossed-dipole antenna over a ground plane without a lens produces radiation patterns with a peak gain of 9.5 dB at 8.3 GHz.
Loss in the lens is also low across the entire operational band. The operational bandwidth of the lens is partially determined by the return loss; between 8 to 9 GHz, the return loss is less than −10 dB, indicating that the majority of the energy is radiated between those frequencies.
Metamaterials comprising of anisotropic low-index metamaterials can be used to improve the broadside directivity of crossed dipole and other antennas and provide a new way to construct compact highly-directive antennas. A uniaxial low-index collimating lens was implemented with cubic unit cells using a combination of split-ring resonators and end-loaded dipoles within metamaterial unit cells.
Example metamaterial designs exhibited useful collimating behavior, with acceptable reflection losses over a 12% bandwidth centered at 8.3 GHz.
Applications
Examples of the present invention include compact high-directivity polarization-insensitive antennas with low mass and volume for use in space-based satellites and other communication systems. Example lens structures may be placed at the aperture of a common, low-directivity antenna in order to collimate the outgoing radiation into a narrow, concentrated beam. Hence, a metamaterial lens may be used to create a larger effective aperture, without a requirement to physically enlarge the real aperture. The larger effective aperture produces higher directivity radiation. In most applications, the antenna may focus in the far-field. Applications also include broad bandwidth antennas for multiple-use antennas and multi-band communication systems.
Antennas according to examples of the present invention are useful for aerospace communication systems, including space-based or airborne antennas, or other applications with mass and volume requirements on the antenna design
Some examples include metamaterials having a unit cell structure including at least one end-loaded dipole. An end-loaded dipole structure may be used to obtain a desired metamaterial property, such as low permittivity (e.g. a permittivity less than 1, and in some examples less than 0.5 or 0.1 at an operating frequency). As illustrated in
An end-loaded dipole may be formed as a printed conducting track on a dielectric substrate. The track width (w in
In other examples, different end-loaded dipole structures may be used, including different configurations of the end-loaded portions, for example including circular, spiral, sinusoidal, disk-shaped or other form of end-loading structure. In some examples, other dipole elements may be used to obtain the desired antenna properties.
Examples of the present invention include metamaterial lenses configured as far-field collimating lens, in particular for use with a circularly-polarized crossed-dipole antenna. A metamaterial may be constructed as a 3D-volumetric metamaterial slab. Zero and low index metamaterials allow the magnitude and phase of the radiated field across the face of the lens to be distributed uniformly, increasing the broadside gain over the feed antenna alone. A fabricated meta-lens increased the measured directivity of a crossed-dipole feed antenna by more than 6 dB, in good agreement with numerical simulations.
Examples include an anisotropic low-index metamaterial structure, used as a far-field collimating lens with an antenna feed such as a dual-polarization crossed-dipole antenna feed. The metamaterial is uniaxial, and has low values for both ∈z and μz that produce 3D collimated beams. A balanced response to both dipoles may be obtained using ∈z=μz, ∈T=μT. The metamaterial uses dual-split ring resonators (DSRR) in the x-y plane (that of the lens faces for a slab shaped lens) for a low permeability response, and end-loaded dipole (ELD) elements in the x-z and y-z planes for a low permittivity response over an operational frequency range. As ∈z or μz approaches zero, the pass-band narrows, improving collimation and directivity of the antenna. In particular, examples include a high-gain, low-profile circularly-polarized antenna using a metamaterial lens.
Modifications and variations of the present invention are possible in light of the above teachings and may be practiced otherwise than as specifically described while within the scope of the appended claims.
The invention is not restricted to the illustrative examples described above. Examples described are not intended to limit the scope of the invention. Changes therein, other combinations of elements, and other uses will occur to those skilled in the art.
This Utility patent application claims priority to U.S. provisional patent application Ser. No. 61/482,402, filed May 4, 2011, the content of which is incorporated herein in its entirety.
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Number | Date | Country | |
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20120280872 A1 | Nov 2012 | US |
Number | Date | Country | |
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61482402 | May 2011 | US |