1. Field of the Invention
The present invention relates to systems and methods for transmitting and/or receiving electromagnetic signals, and in particular to a circularly polarized antenna having an improved axial ratio characteristic.
2. Description of the Related Art
Circularly polarized antennas are used in a variety of applications, including communications between vehicles with metallic structures such as aircraft and spacecraft, and terrestrial assets. Circular polarization is also used in satellite communication antennas because it allows the receiver on the ground to be in any orientation with respect to the satellite without incurring polarization mismatch. It also allows twice the data rate to be used sent using the same bandwidth, because two different data streams can be sent on left and right hand circular polarization.
However, for effective transmission and reception of such circularly polarized signals, the antennas on both the satellite and the ground or air station must have low axial ratio (ratio of the major axis to the minor axis of the polarization ellipse), in order to preserve the polarization purity between the two components (left and right hand polarizations), and minimize interference between the two.
What is needed is a circularly polarized antenna that provides a low axial ratio. The present invention satisfies that need.
To address the requirements described above, the present invention discloses a circularly polarized antenna system. The antenna system comprises a circularly-polarized antenna, and a high-impedance buffer surface, surrounding the circularly polarized antenna, and disposed between the circularly polarized antenna and a ground plane. The width of the high-impedance buffer surface between the circularly-polarized antenna and the ground plane is selected to achieve an H-plane radiation pattern substantially identical to an E-plane radiation pattern over a desired scan angle.
Referring now to the drawings in which like reference numbers represent corresponding parts throughout:
In the following description, reference is made to the accompanying drawings which form a part hereof, and which is shown, by way of illustration, several embodiments of the present invention. It is understood that other embodiments may be utilized and structural changes may be made without departing from the scope of the present invention.
Circularly polarized antenna systems 106 typically transmit signal components that are both right hand circularly polarized, and left hand circularly polarized. If these components are sufficiently isolated, both can be used, providing two channels that can be used effectively doubling the data rate of the communication link by transmitting two different data streams, one on each polarization. If the components are not sufficiently isolated, isolation of each of the two channels becomes more difficult. Also, typically, the axial ratio of a circularly polarized antenna degrades as lower angles (look angles closer to the ground plane of the antenna). For example, in communications between an aircraft 102B and a spacecraft 102A, such as a satellite, the circularly polarized antenna system 106 is required to steer the beam towards the satellite, which, depending on the attitude of the aircraft 102B, is often at low scan angles (shown in
Conventionally, circularly polarized antenna systems 106 on ordinary metal ground planes tend to suffer from poor axial ratio at angles near the ground plane.
The high impedance buffer surface 114 passivates the surrounding ground plane 108 so that the horizontal and vertical components of the radiation from the circularly polarized antenna 110 are substantially equal. This results in an improved axial ratio, and a reduction in the interference between left and right hand circular polarization components. This is useful for satellite communication, particularly for phased arrays on airplanes, in while the array is required to steer to point toward the satellite, which, depending on the orientation of the airplane, may at times be at low angles with respect to the ground plane 108. In one embodiment, the high impedance buffer surface 114 is a two-dimensionally periodic structure, as described in Sievenpiper, D., “High Impedance Electromagnetic Surfaces,” Ph.D. Dissertation, Department of Electrical Engineering, University of California, Los Angeles, Calif. 1999.
In an embodiment in which the circularly polarized antenna 112 is a phased array 110 (such as that which is illustrated in
In the typical application shown in
The resonance frequency and bandwidth of the surface are determined by the inherent sheet capacitance C and sheet inductance L, which are determined by the geometry of the structure of the high-impedance surface 114. Such surfaces can be manufactured as a printed circuit board with embedded capacitors, whose value and arrangement determines the overall sheet capacitance. The sheet inductance is determined by the thickness of the structure t and by the magnetic permeability μ of the material that fills it. Since magnetic materials are typically not effective at high frequencies, and also tend to be lossy, the sheet inductance is essentially determined by the thickness t. In the illustrated example, the built-in capacitors are of the edge-coupled type, but parallel-plate capacitors can also be used for greater sheet capacitance, for lower frequency structures. The resonance frequency ω is determined by the parallel resonant circuit defined by the sheet capacitance and the sheet inductance, and the bandwidth
is determined by the intrinsic impedance of the surface compared to the impedance of free space. These relationships are defined according to Equations (1)-(4) below:
wherein a is a lattice constant, g is a width of a gap between capacitive elements on the substrate, w is a width of each of the capacitive elements, t is a thickness of the substrate, ε0 is the free-space permittivity constant, ε1 is the permittivity constant of the substrate and ε2 is the permittivity constant of the material covering the high impedance high impedance surface, typically air or free space, μ0 is the free-space permeability constant, μ is the permeability constant of the substrate, and Δω is the bandwidth around a center frequency ω0.
For a system operating in the Ku band, the surface may be constructed of 62 mil thick DUROID 5880, available from the ROGERS CORPORATION. The metal plates 116A-116D that form the capacitors are arranged in a 145 mil lattice, with a 20 mil gap between them. Each of the plates 116A-116D has a metal plated via 118A-118D that connects the center of the plate 116A-116D to ground plane 108. In the illustrated example, the lattice spacing is 145 mils, so antenna arrays having gaps between the elements of more than 145 mils will have sufficient space to fill those gaps with at least one period of high impedance material. For more closely-spaced arrays, less than one period of the high-impedance material would fit between the antenna elements, so the area surrounding the array should be covered by a high impedance surface. Such a surface can also be used with single antennas, in addition to phased arrays, when low axial ratio over a broad angular range is important. Further details regarding the design of the high-impedance region 114 can be found in D. Sievenpiper, J. Schaffner, and J. Navarro, “Axial Ratio Improvement in Aperture Antennas Using High-Impedance Ground Plane”, Electronics Letters, Nov. 7, 2002, Vol. 38, No 23, pp. 1411-1412, which is hereby incorporated by reference herein.
The high-impedance surface 114 can be characterized by measuring surface wave transmission characteristics as well as the reflection phase.
The surface 114 supports TM modes below the band gap, and TE modes above the band gap. Within the band gap, and neither type of mode is supported. For the TM modes, the band edge represents a hard cut-off, but leaky TE waves are supported within the gap, and are increasingly bound to the surface at the band edge, so the upper TE band edge is less distinct.
For the exemplary structure shown in
Below the band gap, the high-impedance surface 604 supports a high density of TM surface modes, so it does not enable an antenna with a desirable radiation pattern. This is because these surface waves propagate across the ground plane and radiate from edges and other discontinuities, interfering with the direct radiation from the antenna. However, inside the band gap, the high impedance surface 604 supports neither TM nor TE surface waves, so the radiation pattern is not determined by the shape of the surface. Furthermore, at the resonance frequency ω, the high-impedance surface 604 supports a standing non-propagating wave that radiates normal to the surface 604. Thus, the electric field is spread over a finite region around the aperture 602, and is oriented tangentially to the surface 604. It is this field, and the field at the aperture that determine the radiation pattern of the antenna. On the other hand, the metal surface 502 supports TM surface waves at all frequencies, and shorts TE surface waves at all frequencies. The electric field has no tangential component on a metal surface 602, so the field is only present at the aperture 604. The radiation pattern from an aperture 504 on a metal surface is determined by the aperture 504 and the shape of the ground plane 502.
It is noted that the metal ground plane 502 produces a pattern that is broad in the E-plane, but narrow in the H-plane. This can be attributed to the fact that for low angles 120, horizontally polarized radiation is shorted by the ground plane 502, resulting in a narrowing of the H-plane pattern, but vertically polarized radiation is not shorted, resulting in a broader E-plane. From another point of view, the metal ground plane 502 supports TM waves, but not TE waves. The high-impedance ground plane 602 supports neither type of wave at this frequency, and thus has a symmetrical pattern. The gain is also slightly higher, due to the tangential, non-propagating mode that surrounds the aperture 604.
At higher frequencies, that are still within the bandgap, the high-impedance surface 602 begins to support leaky TE waves. This is apparent in the radiation patterns shown in
Over a broad range of frequencies and angles, the high-impedance surface 602 produces a pattern that is much more symmetrical than the metal surface 502, regardless of the leaky TE waves. Since these waves always have a significant wave vector in the normal direction (and thus are leaky) they radiate away from the surface 602 much faster than TM waves on an ordinary metal surface 502, which requires no such component. The improvement in pattern symmetry can be seen in
One notable data point is at 60 degrees, where the metal surface 502 has an axial ratio of about 10 dB, but the high-impedance surface 602 has an axial ratio ranging from 0 to 5 dB, representing an improvement of 5-10 dB. Similar improvements can be seen at other angles.
This concludes the description of the preferred embodiments of the present invention. The foregoing description of the preferred embodiment of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto. The above specification, examples and data provide a complete description of the manufacture and use of the composition of the invention. Since many embodiments of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended.
Number | Name | Date | Kind |
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6529166 | Kanamaluru | Mar 2003 | B2 |
Number | Date | Country | |
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20050017919 A1 | Jan 2005 | US |