EP1741160A1 - Antenne reseau a microbandes - Google Patents

Antenne reseau a microbandes

Info

Publication number
EP1741160A1
EP1741160A1 EP04750275A EP04750275A EP1741160A1 EP 1741160 A1 EP1741160 A1 EP 1741160A1 EP 04750275 A EP04750275 A EP 04750275A EP 04750275 A EP04750275 A EP 04750275A EP 1741160 A1 EP1741160 A1 EP 1741160A1
Authority
EP
European Patent Office
Prior art keywords
antenna
striplines
patches
transmission line
group
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP04750275A
Other languages
German (de)
English (en)
Inventor
Choon Sae Lee
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Southern Methodist University
Original Assignee
Southern Methodist University
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Southern Methodist University filed Critical Southern Methodist University
Publication of EP1741160A1 publication Critical patent/EP1741160A1/fr
Withdrawn legal-status Critical Current

Links

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q21/00Antenna arrays or systems
    • H01Q21/0006Particular feeding systems
    • H01Q21/0075Stripline fed arrays
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/36Structural form of radiating elements, e.g. cone, spiral, umbrella; Particular materials used therewith
    • H01Q1/38Structural form of radiating elements, e.g. cone, spiral, umbrella; Particular materials used therewith formed by a conductive layer on an insulating support
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q21/00Antenna arrays or systems
    • H01Q21/0006Particular feeding systems
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q21/00Antenna arrays or systems
    • H01Q21/06Arrays of individually energised antenna units similarly polarised and spaced apart
    • H01Q21/061Two dimensional planar arrays
    • H01Q21/065Patch antenna array

Definitions

  • TECHNICAL FIELD A single dielectric layer multipatch, microstrip array antenna design contained in a leaky cavity, to distribute EM (electromagnetic) power between radiating patches and a feed source .
  • the invention relates generally to antennas and, more particularly, to microstrip array antennas.
  • the number of direct satellite broadcast services has substantially increased worldwide and, as it has, the worldwide demand for antennas having the capacity for receiving such broadcast services has also increased. This increased demand has typically been met by reflector, or "dish,” antennas, which are well known in the art.
  • Reflector antennas are commonly used in residential environments for receiving broadcast services, such as the transmission of television channel signals, from geostationary, or equatorial, satellites. Reflector antennas have several drawbacks, though. For example, they are bulky and relatively expensive for residential use.
  • Microstrip antennas for example, require less space, are simpler and less expensive to manufacture, and are more compatible than reflector antennas with printed-circuit technology.
  • Microstrip array antennas i.e., microstrip antennas having an array of microstrips, may be used with applications requiring high directivity.
  • Microstrip array antennas typically require a complex microstrip feed network which contributes significant feed loss to the overall antenna loss.
  • microstrip array antennas are limited to single polarization and to transmitting or receiving only a linearly polarized beam. Such a drawback is particularly significant in many parts of the world where broadcast services are provided using only circularly polarized beams. In such instances, the recipients of the services must resort to less efficient and more expensive, bulky reflector antennas, or microstrip array antennas which utilize a polarizer. A polarizer, however, introduces additional power loss to the antenna and produces a relatively poor quality radiation pattern. Moreover, when dual polarization is needed, two antennas of single polarization are required.
  • a microstrip antenna of the present invention includes a single dielectric layer with a conductive ground plane disposed on one side, and an array of spaced apart radiating patches disposed on the other side of the dielectric layer to form a leaky cavity. Responsive to electromagnetic energy, a directed beam is transmitted from and/or received into the antenna.
  • FIGURE 1 is a perspective view of a planar array antenna
  • FIGURE 2 is an elevation cross-sectional view of the antenna of FIGURE 1 taken along the line 2-2 of FIGURE 1
  • FIGURE 3 is a perspective view of an alternate embodiment of the planar array antenna of FIGURE 1
  • FIGURE 4 is a plan view of a planar array antenna
  • FIGURE 5 is an elevation cross-sectional view of the antenna of FIGURE 4 taken along the line 5-5 of FIGURE 4
  • FIGURE 6 is a plan view of a planar array antenna
  • FIGURE 7 is an elevation cross-sectional view of the antenna of FIGURE 6 taken along the line 7-7 of FIGURE 6
  • FIGURE 8 is a plan view of a planar array antenna
  • FIGURE 9 is an elevation cross-sectional view of the antenna of FIGURE 8 taken along the line 9-9 of FIGURE 8;
  • FIGURE 9 is an elevation cross-sectional view of the antenna of FIGURE 8 taken along the line 9-9 of FIGURE 8;
  • FIGURE 31 is a bottom view of a microstrip of the antenna of FIGURE 30;
  • FIGURE 32 is a plan view of a planar array antenna;
  • FIGURE 33 is an elevation cross-sectional view of the antenna of FIGURE 32 taken along the line 33-33 of FIGURE 32;
  • FIGURE 34 is a plan view of a planar microstrip directional coupler embodying features of the present invention for coupling two EM energy sources to two EM energy destinations; and
  • FIGURE 35 is an elevation cross-sectional view of the coupler of FIGURE 34 taken along the line 35-35 of FIGURE 34.
  • antennas Two types are described hereinafter.
  • One is a linearly polarized antenna that has one feed for a single-mode operation. In this embodiment, crisscrossing or intersecting stripline conductors are not required and the structure is simpler.
  • the other is a dual-mode antenna with two input feeds that are operational independently each other and has crisscrossing or intersecting stripline conductors connecting the patches to the feed connectors. In the dual mode configuration, the antenna acts as two antennas superimposed.
  • Such an antenna may use two feed terminals with the stripline conductors of one terminal being orthogonal to the stripline conductors of the other terminal.
  • Each of the patches in the antenna are connected at one corner, or other point at which two orthogonal modes can be excited, of a patch to a stripline conductor of a first orientation and at an adjacent corner or point to a stripline conductor of a second directional (orthogonal) orientation.
  • the placement of the patches and the stripline conductors are such that nodes of the standing wave are coincident with the stripline intersections to reduce the cross-polarization level and cross talking.
  • the occurrence of the standing wave nodes at each of the stripline conductors produces a predetermined or predefined desirable field distribution.
  • the design would be such to provide uniform distribution of power among the radiating patches.
  • all the patches may be the same physical size and all the interconnecting striplines may retain the same dimensions, thus greatly simplifying the design process and manufacturing tolerances. This is in contrast to prior art designs requiring a number of different parameters for the striplines interconnecting the radiating patch elements to obtain a relatively uniform field distribution among the radiating patches for maximum directivity.
  • a tapered distribution across the radiating patches is preferred to reduce sidelobes despite the fact that the directivity may have to be reduced from an optimum value.
  • a dual-mode antenna can produce two orthogonal linearly polarized radiations or, with some modifications in the feed area, two orthogonal circularly polarized (i.e., right-handed and left-handed) radiations. It will be realized that the dual-mode antenna can be used for a single-mode operation simply by not using the other port. It should also be realized that for optimum results, in a dual mode antenna, the radiating patches should have two-fold symmetry.
  • the stripline conductors alternatively just striplines in the art, form part of the surface of the leaky cavity and thus influence the resonant frequency of the cavity while facilitating the power flow among the radiating patch elements.
  • the striplines act to guide the power flow properly so that the leaked power is channeled in the desired direction, namely radiation, while minimizing other factors to maximize the antenna efficiency.
  • the striplines serve as a conductive path by which the traveling wave is transferred from the feed to the radiating patches.
  • the stripline serves as a channel to bridge the patches and the feed such that energy flows back and forth, thus resulting in some form of standing wave on the channel bridge.
  • the word stripline is intended to apply to any conductive material, other than the radiating patches, that further encloses the cavity and exists on the surface of the dielectric opposite the ground plane, that is used to guide the power flow in the form of a traveling wave, standing wave or combination of the two.
  • conductive microstrips which preferably have a thickness of approximately 1 mil (0.001 inch).
  • Ground planes and edge conductors preferably, also have a thickness of approximately 1 mil, but may be thicker (e.g., 0.125 inches), if desired, for providing structural support to a respective antenna.
  • dielectric material used in accordance with the present invention is preferably fabricated from a mechanically stable material having a relatively low dielectric constant.
  • a dielectric layer may be suitably multilayered to provide a desired dielectric constant.
  • the single dielectric layer, whether or not composite, preferably, has a thickness of between 0.003 ⁇ ⁇ and 0.050 ⁇ ⁇ , although it may have a greater thickness for greater bandwidths .
  • reference to a high-order standing wave comprises one of the high- order standing waves defining modes other than a fundamental mode .
  • ground planes, edge conductors, microstrips e.g., strips and patches
  • conductive materials such as copper, aluminum, silver, and/or gold.
  • bonding of such conductive materials to a dielectric material may, preferably, be achieved using conventional printed-circuit, metallizing, decal transfer, monolithic microwave integrated circuit (MMIC) techniques, chemical etching techniques, or any other suitable technique.
  • MMIC monolithic microwave integrated circuit
  • a dielectric layer may be clad to one of the aforementioned conductive materials.
  • the conductive material may then be selectively etched away from the dielectric layer using conventional chemical etching techniques, to thereby define any of the microstrip patterns described herein.
  • a second dielectric layer may be bonded to the surface of the aforementioned dielectric having the conductive material, using any suitable technique, such as by creating a bond with very thin (e.g., 1.5 mil) thermal bonding film.
  • FIGURES 1-3 the reference numeral 100 designates, in general, a planar microstrip array antenna embodying features of the present invention for transmitting and receiving beams.
  • the antenna 100 preferably includes a generally square, dielectric layer 112.
  • the width 102 and length 102 of the layer 112 are determined by the number and spacing of patches used, discussed below, and, preferably, extends a width and length 102a of at least 0.50 ⁇ ⁇ beyond the outer edges of patches 120.
  • the dielectric layer 112 defines a bottom side 112a to which a conductive ground plane 116 is bonded, and a top side 112b to which an array of conductive radiating patches 120 and a center radiating patch 122 are bonded for forming a radiating cavity within the dielectric layer 112, between the patches 120, 122, the striplines 124 and the ground plane 116.
  • the patches 120 and 122 are generally square in shape, each having four corners 120a and four radiating edges 120b, each edge preferably having a length 120c of about 0.50 ⁇ ⁇ .
  • the patches 120 and 122 are electrically interconnected via either one corner 120a or two diametrically opposed corners 120a to an array of substantially parallel conductive striplines 124.
  • Four tuning stubs 126 extend perpendicularly from two striplines 124.
  • the patches 120 and 122 are preferably spaced apart by a center-to-center distance 160 of approximately 1.0 ⁇ ⁇ .
  • the patches 120 and 122 are preferably arranged in a square array on the top surface 112b preferably having an equal number of rows and columns of patches 120 and 122, exemplified in FIGURE 1 as a square array having five rows and columns of patches 120 and 122 for a total of twenty- five patches 120 and 122 that constitute the antenna 100.
  • each stripline 124 and the width and length of each stub 126 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • a shortening pin 178 is preferably disposed in the antenna 100 electrically connecting the ground plane 116 to the center patch 122 to suppress unwanted mode excitations. Additional shortening pins (not shown) may also be disposed in the antenna 100 connecting the ground plane 116 to patches 120 to further suppress unwanted mode excitations. Alternatively, in some instances, it may be preferable to omit one or all shortening pins 28 from the antenna 100.
  • the dimensions of the patches 120 and 122, the striplines 124, the stubs 126, the apertures 150, and the center-to-center spacing 160 are individually calculated so that a high- order standing wave is generated in the antenna cavity formed within the dielectric 112, and so that fields radiated from the radiating edges 120b interfere constructively with one another to give desired antenna characteristics, such as a high directivity.
  • the number of patches 120 and 122 determines not only the overall size, but also the directivity, of the antenna 100.
  • the sidelobe levels of the antenna 100 are determined by the field distribution among the radiating elements 120.
  • antenna characteristics such as directivity and sidelobe levels
  • antenna characteristics are controlled by the size and the position of each of the patches 120 and 122 and the feeding scheme.
  • the field distribution among the radiating elements is assumed to be as uniform as possible.
  • the foregoing calculations and analysis utilize techniques, such as the cavity-model method and the moment method, discussed, for example, by Lee and Hsieh and will, therefore, not be discussed in further detail herein.
  • a conventional SMA (SubMinature type A) probe 170 is provided for transmitting or receiving beams.
  • Each SMA probe 170 includes, for delivering EM energy to and/or from the antenna 100, an outer conductor 172 which is electrically connected to the ground plane 116, and an inner (or feed) conductor 174 which is electrically connected to the center patch 122.
  • the probe 170 is positioned along a diagonal of the patch 122 proximate to the stripline 124 to optimize the impedance matching of the antenna 100. While it is preferable that the probes 170 be SMA probes, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the inner conductor 174 and the center patch 122, and an appropriate seal (not shown) may be provided where the SMA probe 170 passes through the ground plane 116 to hermetically seal the connection.
  • the other end of the SMA probe 170, not connected to the antenna 100 is connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 100 may be used for receiving or transmitting linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the antenna 100 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 100 is so directed by orienting the top surface 112b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 100 are correctly sized for receiving the beam, then the beam will pass through the apertures 150 and induce a standing wave, which will resonate within the dielectric layer 112.
  • a standing wave induced in the resonant cavity defined by the dielectric layer 112 is communicated through the SMA probe 170 to a receiver, such as a decoder (not shown) .
  • a receiver such as a decoder (not shown) .
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 100 for transmitting signals is reciprocally identical to that of the antenna for receiving signals. The transmission of signals by the antenna 100 will, therefore, not be further described herein .
  • the present invention can take many forms and embodiments. The embodiments described with respect to FIGURES 1 and 2 are intended to illustrate rather than to limit the invention. Accordingly, several variations may be made in the foregoing without departing from the spirit or the scope of the invention.
  • FIGURES 1 and 2 may be configured in a triangular structure for use in a telecom cell.
  • the stubs 126 may be reconfigured to form alternate embodiments, one of which is exemplified and discussed in greater detail below with respect to FIGURE 3.
  • FIGURE 3 depicts the details of a single mode antenna 300 according to an alternate embodiment of the present invention. Since the antenna 300 contains many elements that are identical to those of the antenna 100, these elements are referred to by the same reference numerals and will not be described in any further detail. According to the embodiment of FIG.
  • the reference numeral 400 designates, in general, a planar microstrip array antenna embodying features of the present invention for dual-mode operation, such as transmitting and/or receiving EM beams.
  • the antenna 400 preferably includes a generally square, dielectric layer 412.
  • the width 402 and length 402 of the layer 412 is determined by the number of patches used, discussed below, and, preferably, extends a width and length 402a of at least 0.50 ⁇ ⁇ beyond the outer edges of patches 420.
  • the dielectric layer 412 defines a bottom side 412a to which a conductive ground plane 416 is bonded, and a top side 412b to which an array of conductive radiating patches 420 and a center radiating patch 422 are bonded for forming a resonant cavity within the dielectric layer 412 between the patches 420 and 422, striplines 424 and 424, and the ground plane 416.
  • the patches 420 and 422 are generally square in shape, each having four corners 420a and four radiating edges 420b, each having a length 420c of about 0.50 ⁇ ⁇ .
  • the patches 420 and 422 are electrically interconnected via corners 420a to an array of substantially parallel horizontal conductive striplines 424 and an array of substantially parallel vertical conductive striplines 426 bonded to the dielectric layer 412.
  • Four tuning stubs 428 extend diagonally outwardly from the corners 420a of the center patch 422 and from the horizontal striplines 424 and vertical striplines 426, and are also bonded to the dielectric layer 412.
  • the patches 420 and 422 are preferably spaced apart by a center-to-center distance 460 of slightly less than 1.0 ⁇ ⁇ .
  • the patches 420 and 422 are preferably arranged in a square array on the top surface 412b having an equal odd number of rows and columns (viewed at 45° angles to horizontal in FIGURE 4) of patches 420 and 422, exemplified in FIG. 4 as a square array having five rows and five columns of patches 420 and 422 for a total of twenty-five patches 420 and 422 that constitute the antenna 400.
  • the width 484 (FIG. 4) of each stripline 424 and 426 and the width of each stub 428 are preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • a shortening pin 478 is preferably disposed in the antenna 400 electrically connecting the ground plane 416 to the center patch 422 to suppress unwanted mode excitations. Additional shortening pins (not shown) may also be disposed in the antenna 400 connecting the ground plane 416 to patches 420 to further suppress unwanted mode excitations. Alternatively, in some instances, it may be preferable to omit one or all shortening pins 478 from the antenna 400.
  • the dimensions of the patches 420 and 422, the striplines 424 and 426, the stubs 428, the apertures 450, and the center- to-center spacing 460 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed within the dielectric 412, and so that fields radiated from the radiating edges 420b interfere constructively with one another.
  • the number of patches 420 and 422 determines not only the overall size, but also the directivity, of the antenna 400.
  • the sidelobe levels of the antenna 400 are determined by the field distribution among the radiating elements 420. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the size and the position of each of the patches 420 and 422 and the feeding scheme.
  • the field distribution among the radiating elements 420 is assumed to be as uniform as possible.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Ansoft Corp located in Pittsburgh, Pennsylvania, and will, therefore, not be discussed in further detail herein.
  • two conventional SMA probes 470 are provided for dual mode operation, such as transmitting or receiving beams.
  • Each SMA probe 470 includes, for delivering EM energy to and/or from the antenna 400, an outer conductor 472 which is electrically connected to the ground plane 416, and an inner (or feed) conductor 474 which is electrically connected to the center patch 422.
  • the probe 470 is positioned along a diagonal of the patch 422 proximate to the striplines 424 and 426 to optimize the impedance matching of the antenna 400, and reduce cross- talking and cross-polarization. While it is preferable that the probes 470 be SMA probes, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the inner conductor 474 and the center patch 422, and an appropriate seal (not shown) may be provided where the SMA probe 470 passes through the ground plane 416 to hermetically seal the connection.
  • the other end of the SMA probe 470 not connected to the antenna 400, is connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 400 may be used for receiving or transmitting linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the antenna 400 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 400 is so directed by orienting the top surface 412b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 400 are correctly sized for receiving the beam, then the beam will pass through the apertures 450 and induce a standing wave, which will resonate within the dielectric layer 412.
  • a standing wave induced in the resonant cavity defined by the dielectric layer 412 is communicated through the SMA probe 470 to a receiver such as a decoder (not shown) .
  • the vertical modal excitation becomes orthogonal to that of the horizontal mode so that the cross talk between the two input signals will be minimized. In other words, two orthogonal vertical and horizontal modes can be excited independently.
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 400 for transmitting signals is reciprocally identical to that of the antenna for receiving signals. The transmission of signals by the antenna 400 will, therefore, not be further described herein . It is understood that the present invention can take many forms and embodiments.
  • FIGURES 4 and 5 are intended to illustrate rather than to limit the invention. Accordingly, several variations may be made in the foregoing without departing from the spirit or the scope of the invention.
  • additional patches 420 may be provided for narrowing a beam, or fewer patches 420 may be utilized to reduce the physical space required for the antenna 400 of the present invention.
  • An embodiment utilizing fewer patches is exemplified in FIGURES 6 and 7 by an antenna 600.
  • one of the two SMA probes 470 may be removed (or not attached) for single-mode operation in transmitting and receiving EM beams.
  • the antenna 400 may also be used for receiving and/or transmitting circularly polarized (CP) EM beams.
  • CP circularly polarized
  • FIGURES 8-9 Referring to FIGURES 8 and 9, the reference numeral 800 designates, in general, a planar microstrip array antenna embodying features of the present invention for dual-mode operation, such as transmitting and/or receiving EM beams.
  • the antenna 800 preferably includes a generally square, dielectric layer 812.
  • the width 802 and length 802 of the layer 812 is determined by the number of patches 820 used, discussed below, and, preferably, extends a width and length 802a of at least 0.50 ⁇ ⁇ beyond the outer edges of the patches 820.
  • the dielectric layer 812 defines a bottom side 812a to which a conductive ground plane 816 is bonded, and a top side 812b to which an array of conductive radiating patches 820 and four center radiating patches 822 are bonded for forming a resonant cavity within the dielectric layer 812 between the patches 820 and 822, the striplines 824, 826, and the ground plane 816.
  • the patches 820 and 822 are generally square in shape, each having four corners 820a and four radiating edges 820b, each having a length 820c of about 0.50 ⁇ ⁇ . As viewed in FIG.
  • the patches 820 and 822 are electrically interconnected via corners 820a to an array of substantially parallel horizontal conductive striplines 824, and an array of substantially parallel vertical conductive striplines 826 bonded to the dielectric layer 812.
  • a tuning stub 828 extends diagonally outwardly from a corner 820a of each center patch 822 and toward the center of the antenna 800.
  • the stubs 828 are also bonded to the dielectric layer 812.
  • the patches 820 and 822 are preferably spaced apart by a center-to-center distance 860 of slightly less than 1.0 ⁇ ⁇ .
  • the patches 820 and 822 are preferably arranged in a square array on the top surface 812b having an equal even number of rows and columns (viewed at 45° angles to horizontal in FIG.
  • each stripline 824 and 826 and the width and length of each stub 828 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • a shortening pin 878 is preferably disposed in the antenna 800 electrically connecting the ground plane 816 to each center patch 822 to suppress unwanted mode excitations. Additional shortening pins (not shown) may also be disposed in the antenna 800 connecting the ground plane 816 to patches 820 to further suppress unwanted mode excitations.
  • the dimensions of the patches 820 and 822, the striplines 824 and 826, the stubs 828, the apertures 850, and the center- to-center spacing 860 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed within the dielectric 812, and so that fields radiated from the radiating edges 820b interfere constructively with one another.
  • the number of patches 820 and 822 determines not only the overall size, but also the directivity, of the antenna 800.
  • the sidelobe levels of the antenna 800 are determined by the field distribution among the radiating elements 820 and 822.
  • antenna characteristics such as directivity and sidelobe levels
  • antenna characteristics are controlled by the size and the position of each of the patches 820 and 822 and the feeding scheme.
  • the field distribution among the radiating elements 820 and 822 is assumed to be as uniform as possible.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Anasoft Corp., and will, therefore, not be discussed in further detail herein.
  • two conventional SMA probes 870 are provided for dual mode operation, such as transmitting or receiving beams.
  • Each SMA probe 870 includes, for delivering EM energy to and/or from the antenna 800, an outer conductor 872 which is electrically connected to the ground plane 816, and an inner (or feed) conductor 874 which is electrically connected to a center patch 822.
  • the two SMA probes 870 are thusly connected to two selected adjacent center patches 822.
  • the probes 870 are positioned along a diagonal of the two selected respective center patches 822 proximate to the striplines 824 and 826 to optimize the impedance matching of the antenna 800, and reduce cross- talking and cross-polarization. While it is preferable that the probes 870 be SMA probes, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the ' inner conductor 874 and the center patch 822, and an appropriate seal (not shown) may be provided where the SMA probe 870 passes through the ground plane 816 to hermetically seal the connection.
  • the other end of the SMA probe 870, not connected to the antenna 800 is connectable via a cable (not shown) to a signal generator or to a receiver such as a satellite signal decoder used with television signals.
  • the antenna 800 may be used for receiving or transmitting linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the antenna 800 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 800 is so directed by orienting the top surface 812b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 800 are correctly sized for receiving the beam, then the beam will pass through the apertures 850, and induce a standing wave which will resonate within the dielectric layer 812.
  • a standing wave induced in • the resonant cavity defined within the dielectric layer 812 is communicated through the SMA probes 870 to a receiver, such as a decoder (not shown) .
  • the vertical modal excitation becomes orthogonal, to that of the horizontal mode so that the cross talk between the two input signals may be minimized.
  • two orthogonal vertical and horizontal modes can be excited independently.
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 800 for transmitting signals is reciprocally identical to that of the antenna for receiving signals. The transmission of signals by the antenna 800 will, therefore, not be further described herein . It is understood that the present invention can take many forms and embodiments.
  • FIGURES 8 and 9 are intended to illustrate rather than to limit the invention. Accordingly, several variations may be made in the foregoing without departing from the spirit or the scope of the invention.
  • additional patches 820 may be provided for narrowing a beam, or fewer patches 820 may be utilized to reduce the physical space required for the antenna 800 of the present invention.
  • one of the two SMA probes 870 may be removed (or not attached) for single-mode operation in transmitting or receiving EM beams.
  • the antenna 800 may also be used for receiving and/or transmitting circularly polarized (CP) EM beams.
  • CP circularly polarized
  • FIGURES 10-12 designates, in general, a planar microstrip array antenna embodying features of the present invention for dual-mode operation, such as transmitting and/or receiving EM beams.
  • the antenna 1000 preferably includes generally square, first and second dielectric layers 1012 and 1014.
  • the width 1002 and length 1002 of the layers 1012 and 1014 are determined by the number of patches 1020 and 1022 used, discussed below, and, preferably, extends a width and length 1002a of at least 0.50 ⁇ ⁇ beyond the outer edges of the patches 1020.
  • the dielectric layer 1012 defines a bottom side 1012a to which a conductive ground plane 1016 is bonded, and a top side 1012b to which an array of conductive radiating patches 1020 and four center radiating patches 1022 are bonded for forming a resonant cavity within the dielectric layer 1012 between the patches 1020 and 1022, the striplines 1024 and 1026, and the ground plane 1016.
  • the second dielectric 1014 is bonded to the top side 1012b of the dielectric 1012, such that the patches 1020 and 1022 are interposed between the dielectrics 1012 and 1014.
  • the patches 1020 and 1022 are generally square in shape, each having four corners 1020a and four radiating edges 1020b, each having a length 1020c of about 0.50 ⁇ ⁇ .
  • the patches 1020 and 1022 are electrically interconnected via corners 1020a to an array of substantially parallel horizontal conductive striplines 1024 and an array of substantially parallel vertical conductive striplines 1026 interposed between the dielectric layers 1012 and 1014.
  • a stub 1025 interposed between the dielectric layers 1012 and 1014 extends across respective striplines 1024 and 1026 from corners 1020a of each patch 1020 and 1022.
  • a stripline 1027 interposed between the dielectric layers 1012 and 1014 electrically connects each stub 1025 to two closest stubs 1025.
  • a tuning stub 1028 interposed between the dielectric layers 1012 and 1014 extends outwardly from one stub 1025 of each center patch 1022 and toward the center of the antenna 1000 for impedance matching.
  • the patches 1020 and 1022 are preferably spaced apart by a center-to-center distance 1060 of slightly less than 1.0 ⁇ ⁇ .
  • the patches 1020 and 1022 are preferably arranged in a square array on the top surface 1012b having an equal even number of rows and columns (viewed at 45° angles to horizontal in FIGURE 10) of patches 1020 and 1022, exemplified in FIGURE 12, as a square array having four rows and four columns of patches 1020 and 1022 for a total of sixteen patches 1020 and 1022 that constitute the antenna 1000.
  • the width 1084 (FIG. 10) of each stripline 1024, 1026 and 1027, and the width and length of each stub 1025 and 1028 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • a shortening pin may optionally be disposed in the antenna 1000 to electrically connect the ground plane 1016 to one or more patches 1020 and/or 1022 to suppress unwanted mode excitations.
  • stubs such as 1025, in the planar antennas illustrated, provides impedance matching.
  • the dimensions of the patches 1020 and 1022, the striplines 1024, 1026 and 1027, the stubs 1025 and 1028, the apertures 1050, and the center-to-center spacing 1060 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed within the dielectric 1012, and so that fields radiated from the radiating edges 1020b interfere constructively with one another.
  • the number of patches 1020 and 1022 determines not only the overall size, but also the directivity, of the antenna 1000.
  • the sidelobe levels of the antenna 1000 are determined by the field distribution among the radiating elements 1020 and 1022. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the size and the position of each of the patches 1020 and 1022 and the feeding scheme. To achieve high directivity, the field distribution among the radiating elements 1020 and 1022 is assumed to be as uniform as possible. There are electric field null points in the dielectric layers 1012 and 1014 within the patches 1020 and 1022 and the connecting striplines 1024 and 1026.
  • each SMA probe 1070 includes, for delivering EM energy to and/or from the antenna 1000, an outer conductor 1072 which is electrically connected to the ground plane 1016, and an inner (or feed) conductor 1074 which extends through openings formed in the ground plane 1016 and two center patches 1022, and is electrically connected to a patch 1023.
  • the patch 1023 is preferably square, the sides of which have a length of about 2 millimeters (mm) to about 5 mm and, typically, from about 2.5 mm to about 4.5 mm and, preferably, about 3 mm.
  • the two SMA probes 1070 are thus connected to two selected adjacent center patches 1022.
  • the probes 1070 are positioned along a diagonal of the two selected respective center patches 1022 close to the striplines 1024 and 1026 to optimize the impedance matching of the antenna 1000, and reduce cross-talking and cross- polarization. While it is preferable that the probes 1070 be SMA probes, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the inner conductor 1074 and the selected center patches 1022, and an appropriate seal (not shown) may be provided where the SMA probes 1070 pass through the ground plane 1016 to hermetically seal the connection.
  • an appropriate seal (not shown) may be provided where the SMA probes 1070 pass through the ground plane 1016 to hermetically seal the connection.
  • the other ends of the SMA probes 1070, not connected to the antenna 1000 are connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 1000 may be used for receiving or transmitting linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the antenna 1000 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 1000 is so directed by orienting the top surface 1012b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 1000 are correctly sized for receiving the beam, then the beam will pass through the apertures 1050 (FIGURE 11) and induce a standing wave that will resonate within the dielectric layer 1012.
  • a standing wave induced in the resonant cavity defined within the dielectric layer 1012 is communicated through the SMA probes 1070 to a receiver, such as a decoder (not shown) .
  • a receiver such as a decoder (not shown) .
  • the vertical modal excitation becomes orthogonal to that of the horizontal mode so that the cross talk between the two input signals will be minimized. In other words, two orthogonal vertical and horizontal modes can be excited independently.
  • antennas transmit and receive signals reciprocally. It can be appreciated therefore that operation of the antenna 1000 for transmitting signals is reciprocally identical to that of the antenna for receiving signals. The transmission of signals by the antenna 1000 will, therefore, not be further described herein. It is understood that the present invention can take many forms and embodiments.
  • FIGURES 10-12 are intended to illustrate rather than to limit the invention. Accordingly, several variations may be made in the foregoing without departing from the spirit or the scope of the invention.
  • additional patches 1020 may be provided for narrowing a beam, or fewer patches 1020 may be utilized to reduce the physical space required for the antenna 1000 of the present invention.
  • one of the two SMA probes 1070 may be removed (or not attached) for single-mode operation in transmitting and receiving EM beams.
  • the antenna 1000 may also be used for receiving and/or transmitting circularly polarized (CP) EM beams.
  • CP circularly polarized
  • the reference numeral 1300 designates, in general, a planar microstrip array antenna embodying features of the present invention for dual-mode operation, such as transmitting and/or receiving EM beams.
  • the antenna 1300 preferably includes generally square, first and second dielectric layers 1312 and 1314.
  • the width 1302 and length 1303 of the layers 1312 and 1314 are determined by the number of patches 1320 and 1322 used, discussed below, and, preferably, extends a width and length 1302a of at least 0.50 ⁇ ⁇ beyond the outer edges of the patches 1320.
  • the dielectric layer 1312 defines a bottom side 1312a to which a conductive ground plane 1316 is bonded, and a top side 1312b to which an array of preferably twelve exterior conductive radiating patches 1320 (FIGURE 13) , eight intermediate radiating patches 1321, and four interior radiating patches 1322 are bonded for forming a resonant cavity within the dielectric layer 1312 between the patches 1320, 1321 and 1322, the striplines 1324 and 1352 and the ground plane 1316.
  • the second dielectric 1314 is bonded to the top side 1312b of the dielectric 1312, such that the patches 1320, 1321 and 1322 are interposed between the dielectrics 1312 and 1314.
  • the patches 1320, 1321 and 1322 are generally square in shape, each having four corners 1320a and four radiating edges 1320b, each having a length 1320c of about 0.50 ⁇ ⁇ .
  • the patches 1320, 1321 and 1322 are electrically interconnected via corners 1320a through an array of vertical and horizontal (as viewed in FIGS. 13 and 15) conductive striplines 1324 interposed between the dielectric layers 1312 and 1314.
  • An interpatch area 1352 is defined within each space that is circumscribed by the striplines 1324 and that does not contain a patch 1320, 1321 or 1322.
  • a stub 1325 interposed between the dielectric layers 1312 and 1314 extends across respective striplines 1324 into interpatch areas 1352 from each corner 1320a of each patch 1320, 1321 and 1322, that is adjacent to an interpatch area 1352 bounded by at least one interior patch 1322.
  • a stripline 1326 interposed between the dielectric layers 1312 and 1314 electrically connects each stub 1325 to two closest stubs 1325.
  • a tuning stub 1328 interposed between the dielectric layers 1312 and 1314 extends from each stub 1325 of each patch 1321 and 1322 that is adjacent to an interpatch area 1352 that is bounded by two intermediate patches 1321 and two interior patches 1322, for impedance matching.
  • the patches 1320, 1321 and 1322 are spaced apart by a center-to-center distance 1360 of preferably approximately 1.0 ⁇ ⁇ .
  • the patches 1320, 1321 and 1322 are preferably arranged in a square array on the top surface 1312b having an equal even number of rows and columns of patches 1320, 1321 and 1322.
  • the width 1384 (FIGURE 13) of each stripline 1324 and 1326, and the width and length of each stub 1325 and 1328, is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • a shortening pin may optionally be disposed in the antenna 1300 to electrically connect the ground plane 1316 to one or more patches 1320, 1321 and/or 1322 to suppress unwanted mode excitations .
  • the dimensions of the patches 1320, 1321 and 1322, the striplines 1324 and 1326, the stubs 1325 and 1328, the apertures 1350 and areas 1352, and the center-to-center spacing 1360 are individually calculated so that a high- order standing wave is generated in the antenna cavity formed within the dielectric 1312, and so that fields radiated from the radiating edges 1320b interfere constructively with one another.
  • the number of patches 1320, 1321 and 1322 determines not only the overall size, but also the directivity, of the antenna 1300.
  • the sidelobe levels of the antenna 1300 are determined by the field distribution among the radiating elements 1320, 1321 and 1322. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the position of each of the patches 1320, 1321 and 1322 and the feeding scheme. To achieve high directivity, the field distribution among the radiating elements 1320, 1321 and 1322 is assumed to be as uniform as possible. There are electric field null points within the dielectric layers 1312 between the patches 1320, 1321 and 1322 and the connecting striplines 1324 and 1326 and the ground plane 1316.
  • each SMA probe 1370 includes, for delivering EM energy to and/or from the antenna 1300, an outer conductor 1372 which is electrically connected to the ground plane 1316, and an inner (or feed) conductor 1374 which extends through openings formed in the ground plane 1316 and two interior patches 1322, and is electrically connected to a patch 1323.
  • the patch 1323 is preferably square, the sides of which have a length of about 2 mm to about 5 mm and, typically, from about 2.5 mm to about 4.5 mm and, preferably, about 3 mm.
  • the two SMA probes 1370 are thus connected to two adjacent center patches 1322.
  • the probes 1370 are positioned along a diagonal of the two selected respective center patches 1322 proximate to the striplines 1324 to optimize the impedance matching of the antenna 1300, and reduce cross-talking and cross-polarization. While it is preferable that the probes 1370 be SMA probes, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the inner conductor 1374 and the selected center patches 1322, and an appropriate seal (not shown) may be provided where the SMA probes 1370 pass through the ground plane 1316 to hermetically seal the connection.
  • the other ends of the SMA probes 1370, not connected to the antenna 1300 are connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 1300 may be used for receiving or transmitting linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the antenna 1300 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 1300 is so directed by orienting the top surface 1312b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 1300 are correctly sized for
  • the beam will pass through the apertures 1350 and areas 1352, and induce a standing wave, which will resonate within the dielectric layer 1312.
  • a standing wave induced in the resonant cavity defined by the dielectric layer 1312 is communicated through the SMA probes 1370 to a receiver, such as a decoder (not shown) .
  • the vertical modal excitation becomes orthogonal to that of the horizontal mode so that the cross talk between the two input signals will be minimized. In other words, two orthogonal vertical and horizontal modes can be excited independently. It is well known that antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 1300 for transmitting signals is reciprocally identical to that of the antenna for receiving signals.
  • the transmission of signals by the antenna 1300 will, therefore, not be further described herein. It is understood that the present invention can take many forms and embodiments. The embodiments described with respect to FIGURES 13-15 are intended to illustrate rather than to limit the invention. Accordingly, several variations may be made in the foregoing without departing from the spirit or the scope of the invention. For example, additional patches 1320 may be provided for narrowing a beam, or fewer patches 1320 may be utilized to reduce the physical space required for the antenna 1300 of the present invention. In another example, one of the two SMA probes 1370 may be removed (or not attached) for single-mode operation in transmitting and receiving EM beams. The antenna 1300 may also be used for receiving and/or transmitting circularly polarized (CP) EM beams.
  • CP circularly polarized
  • FIGURES 16-18 designate, in general, a linear microstrip array antenna embodying features of the present invention for dual-mode operation, such as transmitting and receiving EM beams.
  • the linear array antenna 1600 is configured for producing a narrow beam in the direction of the array, but a broad beam in the direction perpendicular to the array.
  • the antenna 1600 preferably includes a generally rectangular- shaped, dielectric layer 1612.
  • the length 1602 of the layer 1612 is determined by the number of patches 1620 used, discussed below, and, preferably, extends a length 1602a and width 1604a of at least 0.50 ⁇ ⁇ beyond the outer edges of the patches 1620.
  • the dielectric layer 1612 defines a bottom side 1612a to which a conductive ground plane 1616 is bonded, and a top side 1612b to which an array of conductive radiating patches 1620 (FIGURE 16) and a center radiating patch 1622 are bonded for forming a resonant cavity within the dielectric layer 1612 between the patches 1620 and 1622, striplines 1620, and the ground plane 1616.
  • the patches 1620 and 1622 are generally square in shape, each having four corners 1620a, and four radiating edges 1620b, each having a length 1620c of about 0.50 ⁇ ⁇ .
  • the patches 1620 and 1622 are electrically interconnected via corners 1620a and crossed conductive striplines 1624 bonded to the dielectric layer 1612.
  • Two tuning stubs 1628 extend diagonally outwardly from two corners 1620a of the center patch 1622, and are also bonded to the dielectric layer 1612.
  • the patches 1620 and 1622 are preferably spaced apart by a center-to-center distance 1660 of slightly less than 1.0 ⁇ ⁇ .
  • the patches 1620 and 1622 are preferably arranged in a single-column array on the top surface 1612b, exemplified in FIG. 16 as having two patches 1620 on each side of a single patch 1622 for a total of five patches 1620 and 1622 that constitute the antenna 1600.
  • the width 1684 (FIG. 16) of each stripline 1624 and the length and width of each stub 1628 are preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • a shortening pin 1678 is preferably disposed in the antenna 1600 electrically connecting the ground plane 1616 to the center patch 1622 to suppress unwanted mode excitations.
  • Additional shortening pins may also be disposed in the antenna 1600 connecting the ground plane 1616 to patches 1620 to further suppress unwanted mode excitations. Alternatively, in some instances, it may be preferable to omit one or all shortening pins 1678 from the antenna 1600.
  • the dimensions of the patches 1620 and 1622, the striplines 1624, the stubs 1628, the apertures 1650, and the center-to- center spacing 1660 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed within the dielectric 1612, and so that fields radiated from the radiating edges 1620b interfere constructively with one another.
  • the number of patches 1620 and 1622 determines not only the overall size, but also the directivity, of the antenna 1600.
  • the sidelobe levels of the antenna 1600 are determined by the field distribution at the radiating elements 1620 and 1622. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the size and the position of each of the patches 1620 and 1622 and the feeding scheme. To achieve high directivity, the field distribution at the radiating elements 1620 and 1622 is assumed to be as uniform as possible.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Anasoft Corp., and will, therefore, not be discussed in further detail herein.
  • each SMA probe 1670 includes, for delivering EM energy to and/or from the antenna 1600, an outer conductor 1672 which is electrically connected to the ground plane 1616, and an inner (or feed) conductor 1674 which is electrically connected to the center patch 1622.
  • the probe 1670 is positioned along a diagonal of the patch 1622 close to the stripline 1650 to optimize the impedance matching of the antenna 1600 and reduce cross-talking and cross-polarization. While it is preferable that the probes 1670 be SMA probes, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the inner conductor 1674 and the center patch 1622, and an appropriate seal (not shown) may be provided where the SMA probe 1670 passes through the ground plane 1616 to hermetically seal the connection.
  • the other ends of the SMA probes 1670, not connected to the antenna 1600 are connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 1600 may be used for receiving or transmitting linearly polarized (LP) EM beams.
  • the antenna 1600 is so directed by orienting the top surface 1612b toward the source of the beam so that it is generally perpendicular to the direction of the beam.
  • the beam will pass through the apertures 1650 and induce a standing wave that will resonate within the dielectric layer 1612.
  • a standing wave induced in the resonant cavity defined within the dielectric layer 1612 is communicated through the SMA probe 1670 to a receiver such as a decoder (not shown) .
  • the vertical modal excitation becomes orthogonal to that of the horizontal mode so that the cross talk between the two input signals will be minimized. In other words, two orthogonal vertical and horizontal modes can be excited independently. It is well known that antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 1600 for transmitting signals is reciprocally identical to that of the antenna for receiving signals.
  • the transmission of signals by the antenna 1600 will, therefore, not be further described herein. It is understood that the present invention can take many forms and embodiments. The embodiments described with respect to FIGURES 16-18 are intended to illustrate rather than to limit the invention. Accordingly, several variations may be made in the foregoing without departing from the spirit or the scope of the invention. For example, additional patches 1620 may be provided for narrowing a beam, or fewer patches 1620 may be utilized to reduce the physical space required for the antenna 1600 of the present invention.
  • the antenna 1600 may also be used for receiving and/or transmitting circularly polarized (CP) EM beams.
  • CP circularly polarized
  • the outer edges of the dielectric layer 1612 may be wrapped with conducting foil, spaced apart from the patches 1620, to thereby form edge conductors and reduce surface-mode excitation and increase the gain of the antenna. In some instances, it may be preferable to omit the shortening pin 1678 from the antenna 1600.
  • the antenna 1800 may be adapted for single mode operation in transmitting and receiving EM beams by removing (or not attaching) one of the two SMA probes 1670 and by not bonding one stub 1628 and striplines 1624 that are substantially parallel to the remaining stub 1628.
  • VERY-HIGH-GAIN ANTENNA APPLICATIONS SUCH AS FOR DIRECT BROADCAST SATELLITE
  • FIGURES 19-20 the reference numeral 1900 designates, in general, a planar microstrip array antenna embodying features of the present invention for single-mode operation, such as transmitting or receiving beams.
  • the antenna 1900 includes a generally square, dielectric layer 1912.
  • the width 1902 and length 1903 of the layer 1912 may be equal or different, and are determined by the number of patches used, as discussed below, and, preferably, extends a width and length 1902a of at least 0.50 ⁇ ⁇ beyond the outer edges of patches 1920.
  • the dielectric layer 1912 defines a bottom side 1912a to which a conductive ground plane 1916 is bonded, and a top side 1912b to which an array of conductive radiating patches 1920 are bonded for forming a resonant cavity within the dielectric layer 1912 between the patches 1920, the striplines 1924 and the ground plane 1916.
  • the patches 1920 are generally square in shape, having four corners 1920a and four radiating edges 1920b, each having a length 1920c of about 0.50 ⁇ ⁇ .
  • the patches 1920 are electrically interconnected via either one corner 1920a or two opposing corners 1920a to an array of parallel vertical conductive striplines 1924, which in turn are electrically interconnected via a horizontal conductive transmission line 1926.
  • the striplines 1924 and transmission line 1926 are bonded to the dielectric layer 1912.
  • the patches 1920 are spaced apart by a vertical (as viewed in FIG. 19) center-to- center distance 1960 of preferably about 1 ⁇ ⁇ .
  • the patches 1920 are preferably arranged in a plurality of vertical (as viewed in FIG. 19) columns on the top surface 1912b, exemplified in FIG. 19 as eight vertical (as viewed in FIG. 19) columns 1928 (depicted in dashed outline) , offset against one another, above and below the horizontal transmission line 1926, each column comprising two patches 1920, for a total of thirty-two patches 1920 that constitute the antenna 1900.
  • each stripline 1924 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • Each transmission line 1926 includes a first portion 1926a, a second portion 1926b and a third portion 1926c.
  • Each first portion 1926a is preferably sized to have a characteristic impedance of about 100 ohms when the input impedance is about 50 ohms.
  • the width and length of each second portion 1926b is determined by a quarter- wavelength transformer, such that the incoming wave from the feed is substantially transmitted, i.e., that the input impedance at a feed line 1974 is properly matched.
  • each third portion 1926c of the transmission line 1926 is determined, such that a traveling wave from the feed line 1974 is not reflected at junctions 1927a and 1927b. Accordingly, the length of each third portion 1926c is preferably about 1 ⁇ ⁇ to ensure that the differences between the phase of the traveling wave at junctions 1927a and 1927b is as close to 360° as possible.
  • the width of each third portion 1926c is preferably sized such that the characteristic impedance is about one half of the characteristic impedance of the striplines 1924.
  • the dimensions of the patches 1920, the striplines 1924 and 1926, the apertures 1950, and the center-to-center spacing 1960 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed within the dielectric 1912, and so that fields radiated from the radiating edges 1920b interfere constructively with one another.
  • the number of patches 1920 determines not only the overall size, but also the directivity, of the antenna 1900.
  • the sidelobe levels of the antenna 1900 are determined by the field distribution at the radiating edges 1920b. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the size and the position of each of the patches 1920 and the feeding scheme. To achieve high directivity, the field distribution among the radiating elements 1920 is assumed to be as uniform as possible.
  • one or more shortening pins may be disposed in the antenna 1900 electrically connecting together the ground plane, patches, and/or striplines to suppress unwanted mode excitations.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Anasoft Corp., and will, therefore, not be discussed in further detail herein.
  • a conventional SMA probe 1970 (FIGURE 20) is provided for single mode operation, such as transmitting or receiving beams.
  • the SMA probe 1970 includes, for delivering EM energy to and/or from the antenna 1900, an outer conductor 1972 which is electrically connected to the ground plane 1916, and an inner (or feed) conductor 1974 which is electrically connected and centrally positioned along the transmission line 1926 between the portions 1926a to optimize the impedance matching and proper radiation patterns of the antenna 1900. While it is preferable that the probe 1970 be an SMA probe, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections. For example, a conductive adhesive (not shown) may be used to bond and maintain contact between the inner conductor 1974 and the center patch 1922, and an appropriate seal (not shown) may be provided where the SMA probe 1970 passes through the ground plane 1916 to hermetically seal the connection.
  • the other end of the SMA probe 1970 is connectable via a cable (not shown) to a signal generator or- to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 1900 may be used for transmitting or receiving linearly polarized (LP) EM beams.
  • LP linearly polarized
  • an incoming signal from the SMA probe 1970 travels as a traveling wave along the transmission line 19.26 through the first portion 1926a which acts as a quarter-wavelength transformer to transport the EM power to the two branches 1926b and 1926c and four striplines 1924 of each branch 1926b and 1926c with minimal reflection.
  • the EM power is transmitted through the striplines 1924 to the array of patches 1920.
  • the antenna 1900 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 1900 is so directed by orienting the top surface 1912b toward the source of the beam so that it is generally perpendicular to the direction of the beam.
  • the beam will pass through the apertures 1950 and induce a high-order standing wave which will resonate within the resonant cavity formed within the dielectric layer 1912, and pass EM power through the striplines 1924 and transmission lines 1926 to the SMA probe 1970.
  • the EM power is then passed from the SMA probe 1970 through a cable (not shown) and delivered to a receiver, such as a decoder (not shown) .
  • FIGURES 21-22 the reference numeral 2100 designates, in general, a planar microstrip array antenna embodying features of the present invention for single-mode operation, such as transmitting or receiving beams.
  • the antenna 2100 includes a generally square, dielectric layer 2112.
  • the width 2102 and length 2103 (FIG. 21) of the layer 2112 is determined by the number of patches used, as discussed below, and, preferably, extends a width and length 2102a of at least 0.50 ⁇ ⁇ beyond the outer edges of patches 2120 and stripline 2126.
  • the dielectric layer 2112 defines a bottom side 2112a to which a conductive ground plane 2116 is bonded, and a top side 2112b to which an array of conductive radiating patches 2120 are bonded for forming a resonant cavity within the dielectric layer 2112 between the patches 2120, the striplines 2124, and the ground plane 2116.
  • the patches 2120 are generally square in shape, having four corners 2120a and four radiating edges 2120b, each edge having a length 2120c of about 0.50 ⁇ ⁇ .
  • the patches 2120 are electrically interconnected via one corner 2120a to one of an array of four conductive striplines 2124, which in turn are electrically interconnected via a conductive stripline 2126.
  • the striplines 2124 and transmission line 2126 are bonded to the dielectric layer 2112.
  • the patches 2120 are spaced apart by a vertical (as viewed in FIGURE 21) center- to-center distance 2160 of preferably about 1 ⁇ ⁇ .
  • the patches 2120 are preferably arranged in a plurality of eight columns on the top surface 2112b, representatively exemplified in FIG. 21 by columns 2114 and 2116, each of which columns comprises four patches 2120, for a total of thirty-two patches 2120 that constitute the antenna 2100.
  • the width of each stripline 2124 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • Each transmission line 2126 includes a first portion 2126a preferably configured to have a characteristic impedance of about 100 ohms for an input impedance of about 50 ohms, with a feed line centrally positioned on the stripline 2126, as discussed below with respect to the SMA probe 2170, to ensure proper radiation.
  • Each transmission line 2126 further includes a second portion 2126b preferably configured as a quarter-wavelength transformer to have minimal reflection at the junction with the striplines 2124.
  • the dimensions of the patches 2120, the striplines 2124 and 2126, the apertures 2150, and the center-to-center spacing 2160 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed within the dielectric 2112, and so that fields radiated from the radiating edges 2120a interfere constructively with one another.
  • the number of patches 2120 determines not only the overall size, but also the directivity, of the antenna 2100.
  • the sidelobe levels of the antenna 2100 are determined by the field distribution among the radiating elements 2120. Therefore, antenna characteristics, such as directivity and sidelobe levels are controlled by the size and the position of each of the patches 2120 and the feeding scheme.
  • the field distribution among the radiating elements 2120 is assumed to be as uniform as possible.
  • one or more shortening pins may be disposed in the antenna 2100 electrically connecting together the ground plane, patches and/or striplines to suppress unwanted mode excitations.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Anasoft Corp., and will, therefore, not be discussed in further detail herein.
  • a conventional SMA probe 2170 (FIGURE 22) is provided for single mode operation, such as transmitting or receiving beams.
  • Each SMA probe 2170 includes, for delivering EM energy to and/or from the antenna 2100, an outer conductor 2172 which is electrically connected to the ground plane 2116, and an inner (or feed) conductor 2174 which is electrically connected and centrally positioned along the transmission line 2126 between the portions 2126a and 2126b to optimize the impedance matching of the antenna 2100, and induce centrally-peaked radiation. While it is preferable that the probe 2170 be an SMA probe, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the inner conductor 2174 and the center stripline 2126, and an appropriate seal (not shown) may be provided where the SMA probe 2170 passes through the ground plane 2116 to hermetically seal the connection.
  • an appropriate seal (not shown) may be provided where the SMA probe 2170 passes through the ground plane 2116 to hermetically seal the connection.
  • the other end of the SMA probe 2170, not connected to the antenna 2100 is connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 2100 may be used for transmitting or receiving linearly polarized (LP) EM beams.
  • LP linearly polarized
  • an incoming signal from the SMA probe 2170 travels as a traveling wave along the transmission line 2126 through the first portion 2126a and the second portion 2126b, which behaves as a quarter- wavelength transformer to transport the EM power to the four striplines 2124 with minimal reflection.
  • the EM power is transmitted through the striplines 2124 to the array of patches 2120.
  • the patches 2120 then induce a high-order standing wave for proper radiation through the apertures 2150 of the antenna 2100. It is well known that antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 2100 for transmitting signals is reciprocally identical to that of the antenna for receiving signals.
  • the antenna 2100 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 2100 is so directed by orienting the top surface 2112b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 2100 are correctly sized for receiving the beam, then the beam will pass through the apertures 2150 and induce a standing wave that will resonate within the dielectric layer 2112.
  • a standing wave induced in the resonant cavity defined within the dielectric layer 2112 is transmitted through striplines 2124, transmission line 2126, and the SMA probe 2170 and is delivered to a receiver, such as a decoder (not shown) .
  • a receiver such as a decoder (not shown) .
  • the present invention can take many forms and embodiments. The embodiments described with respect to FIGURES 21 and 22 are intended to illustrate rather than to limit the invention. Accordingly, several variations may be made in the foregoing without departing from the spirit or the scope of the invention. For example, additional patches 2120 may be provided for narrowing a beam, or fewer patches 2120 may be utilized to reduce the physical space required for the antenna 2100 of the present invention .
  • FIGURES 23-24 the reference numeral 2300 designates, in general, a planar microstrip array antenna embodying features of the present invention for dual-mode operation, such as transmitting and receiving beams.
  • the antenna 2300 includes a generally square, dielectric layer 2312.
  • the width 2302 and length 2303 (FIG. 23) of the layer 2312 is determined by the number of patches used, as discussed below, and, preferably, extends a width and length 2302a of at least 0.50 ⁇ ⁇ beyond the outer edges of the patches 2320 and transmission lines 2325 and 2327.
  • the dielectric layer 2312 defines a bottom side 2312a to which a conductive ground plane 2316 is bonded, and a top side 2312b to which an array of conductive radiating patches 2320 are bonded for forming a resonant cavity within the dielectric layer 2312 between the patches 2320, the striplines 2324 and 2326, and the ground plane 2316.
  • the patches 2320 are generally square in shape, having four corners 2320a and four radiating edges 2320b, each edge having a length 2320c of about 0.50 ⁇ ⁇ .
  • the patches 2320 are electrically interconnected via two adjacent corners 2320a, one of which adjacent corners is electrically connected to one of an array of eight vertical conductive striplines 2324, and the other of which adjacent corners is electrically connected to one of an array of eight horizontal conductive striplines 2326.
  • the vertical striplines 2324 are electrically interconnected via a horizontal conductive transmission line 2325
  • the horizontal striplines 2326 are electrically interconnected via a vertical conductive transmission line 2327.
  • the striplines 2324 and 2326 and the transmission lines 2325 and 2327 are bonded to the dielectric layer 2312.
  • the patches 2320 are spaced apart by a center-to-center distance 2360 of preferably about 1 ⁇ ⁇ .
  • the patches 2320 are preferably arranged in a plurality of rows and columns on the top surface 2312b, representatively exemplified in FIG. 23 by a row 2328 and a column 2329, wherein each row and column comprises four patches 2320, for a total of thirty-two patches 2320 that constitute the antenna 2300.
  • the width of each stripline 2324 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • Each transmission line 2325 and 2327 includes a first portion 2326a and 2326a, preferably configured to have a characteristic impedance of about 100 ohms for an input impedance of about 50 ohms, with a feed line centrally positioned on the stripline 2325, as discussed below with respect to the SMA probe 2370, to ensure proper radiation.
  • Each transmission line 2325 and 2327 further includes a second portion 2325b and 2327b preferably configured as a quarter-wavelength transformer to have minimal reflection at the junction with the striplines 2324 and 2326.
  • the dimensions of the patches 2320, the striplines 2324 and 2326, the apertures 2350, and the center-to-center spacing 2360 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed within the dielectric 2312, and so that fields radiated from the radiating edges 2320b interfere constructively with one another.
  • the number of patches 2320 determines not only the overall size, but also the directivity, of the antenna 2300.
  • the sidelobe levels of the antenna 2300 are determined by the field distribution among the radiating elements 2320. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the size and the position of each of the patches 2320 and the feeding scheme.
  • the field distribution among the radiating elements 2320 is assumed to be as uniform as possible.
  • one or more shortening pins may be disposed in the antenna 2300 electrically connecting together the ground plane, patches, and/or striplines to suppress unwanted mode excitations.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Anasoft Corp., and will, therefore, not be discussed in further detail herein.
  • Each SMA probe 2370 includes, for delivering EM energy to and/or from the antenna 2300, an outer conductor 2372 which is electrically connected to the ground plane 2316, and an inner (or feed) conductor 2374 which is electrically connected and centrally positioned along each transmission line 2325 and 2327 to optimize the impedance matching of the antenna 2300 and the radiation efficiency. While it is preferable that the probes 2370 be SMA probes, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between each inner conductor 2374 and each transmission line 2325 and 2327, and an appropriate seal (not shown) may be provided where the SMA probe 2370 passes through the ground plane 2316 to hermetically seal the connection.
  • an appropriate seal (not shown) may be provided where the SMA probe 2370 passes through the ground plane 2316 to hermetically seal the connection.
  • the other end of the SMA probe 2370, not connected to the antenna 2300 is connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 2300 may be used for transmitting and/or receiving linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the incoming signal travels as a traveling wave along the transmission line 2325 through the first portion 2325a and the second portion 2325b, which behaves as a quarter- wavelength transformer to transport the EM power to the four striplines 2324 with minimal reflection.
  • the EM power is transmitted through the striplines 2324 to the array of patches 2320.
  • the patches 2320 then induce a high-order standing wave for proper radiation through the apertures 2350 of the antenna 2300.
  • the vertical modal excitation becomes orthogonal to that of the horizontal mode so that the cross talk between the two input signals will be minimized.
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 2300 for transmitting signals is reciprocally identical to that of the antenna for receiving signals.
  • the antenna 2300 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 2300 is so directed by orienting the top surface 2312b toward the source of the beam so that it is generally perpendicular to the direction of the beam.
  • the beam will pass through the apertures 2350 and induce a standing wave that will resonate within the dielectric layer 2312.
  • a standing wave induced in the resonant cavity defined within the dielectric layer 2312 is transmitted either through the striplines 2324 and transmission line 2325, and/or through the striplines 2326 and transmission line 2327, to an SMA probe 2370 and delivered to a receiver, such as a decoder (not shown) .
  • a receiver such as a decoder (not shown) .
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 2300 for transmitting signals is reciprocally identical to that of the antenna for receiving signals. The transmission of signals by the antenna 2300 will, therefore, not be further described herein.
  • FIGURES 25-26 the reference numeral 2500 designates, in general, a planar microstrip array antenna embodying features of the present invention for single-mode operation, such as transmitting or receiving beams.
  • the antenna 2500 includes a generally square, dielectric layer 2512.
  • the width 2502 and length 2503 of the layer 2512 may be equal or unequal and are determined by the number of patches used, as discussed below, and, preferably, extends a width and length 2502a of at least 0.50 ⁇ ⁇ beyond the outer edges of patches 2520.
  • the dielectric layer 2512 defines a bottom side 2512a to which a conductive ground plane 2516 is bonded, and a top side 2512b to which an array of conductive radiating patches 2520 are bonded for forming a resonant cavity within the dielectric layer 2512, between the ground plane 2516 and the patches 2520 and striplines 2524.
  • the patches 2520 are generally square in shape, having four corners 2520a and four radiating edges 2520b, each having a length 2520c of about 0.5 ⁇ ⁇ .
  • the patches 2520 are electrically interconnected via either one corner 2520a or two opposing corners 2520a to an array of substantially parallel vertical conductive striplines 2524, which in turn are electrically interconnected via a substantially horizontal conductive transmission line 2526, which striplines 2524 and transmission line 2526 are bonded to the dielectric layer 2512.
  • the patches 2520 are spaced apart by a vertical (as viewed in FIG. 25) center-to-center distance 2560 of preferably about 1 ⁇ .
  • the patches 2520 are preferably arranged in a plurality of vertical (as viewed in FIG. 25) columns on the top surface 2512b, above and below the transmission line 2526, representatively exemplified by a column 2528, depicted in dashed outline.
  • each stripline 2524 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • the transmission line 2526 includes a first portion 2526a preferably configured to have a characteristic impedance of about 100 ohms for an input impedance of about 50 ohms, with a feed line preferably centrally positioned on the transmission line 2526, as discussed below with respect to the SMA probe 2570, to ensure proper radiation.
  • the transmission line 2526 further includes two second portions 2526b so configured to have minimal reflection at the junction with the striplines 2524.
  • the dimensions of the patches 2520, the striplines 2524, the transmission line 2526, the apertures 2550, and the center- to-center spacing 2560 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed within the dielectric 2512, and so that fields radiated from the radiating edges 2520b interfere constructively with one another.
  • the number of patches 2520 determines not only the overall size, but also the directivity, of the antenna 2500.
  • the sidelobe levels of the antenna 2500 are determined by the field distribution among the radiating elements 2520. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the size and the position of each of the patches 2520 and the feeding scheme.
  • the field distribution at the radiating elements 2520 is assumed to be as uniform as possible.
  • one or more shortening pins may be disposed in the antenna 2500 electrically connecting together the ground plane, patches, and/or striplines to suppress unwanted mode excitations.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Anasoft Corp., and will, therefore, not be discussed in further detail herein.
  • a conventional SMA probe 2570 (FIGURE 26) is provided for single-mode operation, such as transmitting or receiving beams.
  • Each SMA probe 2570 includes, for delivering EM energy to or from the antenna 2500, an outer conductor 2572 which is electrically connected to the ground plane 2516, and an inner (or feed) conductor 2574 which is electrically connected and centrally positioned along the transmission line 2526 to optimize the impedance matching of the antenna 2500, and the antenna aperture efficiency. While it is preferable that the probe 2570 be an SMA probe, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the inner conductor 2574 and the center stripline 2526a, and an appropriate seal (not shown) may be provided where the SMA probe 2570 passes through the ground plane 2516 to hermetically seal the connection.
  • an appropriate seal (not shown) may be provided where the SMA probe 2570 passes through the ground plane 2516 to hermetically seal the connection.
  • the other end of the SMA probe 2570, not connected to the antenna 2500 is connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 2500 may be used for transmitting or receiving linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the incoming signal travels as 1 a traveling wave along the transmission line 2526 through the first portion 2526a to transport the EM power to the two branches 2526b and, subsequently, striplines 2524 with minimal reflection.
  • the EM power is transmitted through the striplines 2524 to the array of patches 2520.
  • the patches 2520 then induce a high- order standing wave for proper radiation through the apertures 2550 of the antenna 2500.
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 2500 for transmitting signals is reciprocally identical to that of the antenna for receiving signals.
  • the antenna 2500 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 2500 is so directed by orienting the top surface 2512b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 2500 are correctly sized for receiving the beam, then the beam will pass through the apertures 2550 and induce a standing wave that will resonate within the resonant cavity of the array of patches 2520 in the dielectric layer 2512.
  • a standing wave induced in the resonant cavity defined in the dielectric layer 2512 leaks the EM power through the transmission line network comprising the striplines 2524 and 2526 to the SMA probe 2570, and is delivered to a receiver, such as a decoder (not shown) .
  • a receiver such as a decoder (not shown) .
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 2500 for transmitting signals is reciprocally identical to that of the antenna for receiving signals. The transmission of signals by the antenna 2500 will, therefore, not be further described herein. It is understood that the present invention can take many forms and embodiments. The embodiments described with respect to FIGURES 25 and 26 are intended to illustrate rather than to limit the invention.
  • FIGURES 27-28 Referring to FIGURES 27 and 28, the reference numeral 2700 designates, in general, a planar microstrip array antenna embodying features of the present invention for single-mode operation, such as transmitting or receiving beams.
  • the antenna 2700 includes a generally square, dielectric layer 2712.
  • the width 2702 and length 2703 of the layer 2712 may be equal or unequal, and are determined by the number of patches used, discussed below, and, preferably, extends a width and length 2702a of at least 0.50 ⁇ ⁇ beyond the outer edges of patches 2720.
  • the dielectric layer 2712 defines a bottom side 2712a to which a conductive ground plane 2716 is bonded and a top side 2712b to which an array of conductive radiating patches 2720 (FIGURE 27) are bonded for forming a resonant cavity within the dielectric layer 2712, between the ground plane and the patches 2720 and striplines 2724.
  • the patches 2720 are generally square in shape, having four corners 2720a and four radiating edges 2720b, each having a length 2720c of about 0.5 ⁇ ⁇ .
  • the patches 2720 are electrically interconnected via two, three or four corners 2720a to an array of substantially horizontal and vertical conductive striplines 2724, which in turn are electrically interconnected via a substantially horizontal conductive transmission line 2726.
  • the striplines 2724 and transmission line 2726 are bonded to the dielectric layer 2712.
  • the width of each stripline 2724 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • the transmission line 2726 includes a first portion 2726a preferably configured to have a characteristic impedance of about 100 ohms for an input impedance of about 50 ohms, with a feed line 2774 centrally positioned on the transmission line 2726, as discussed below with respect to the SMA probe 2770, to ensure proper radiation.
  • the transmission line 2726 further includes two second portions 2726b preferably configured as quarter-wavelength transformers to have minimal reflection. Then the signal from 2726b travels through further quarter-wavelength transformers, such that the power through the vertical transmission lines 2724 are equally distributed among one another.
  • the dimensions of the patches 2720, the striplines 2724 and transmission line 2726, the apertures 2750, and the center- to-center spacing 2760 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed within the dielectric 2712, and so that fields radiated from the radiating edges 2720b interfere constructively with one another.
  • the number of patches 2720 determines not only the overall size, but also the directivity, of the antenna 2700.
  • the sidelobe levels of the antenna 2700 are determined by the field distribution at the radiating edges 2720b. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the size and the position of each of the patches 2720 and the feeding scheme.
  • the field distribution among the radiating elements 2720 is assumed to be as uniform as possible.
  • one or more shortening pins may be disposed in the antenna 2700 electrically connecting together the ground plane, patches, and/or striplines to suppress unwanted mode excitations.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Anasoft Corp., and will, therefore, not be discussed in further detail herein.
  • a conventional SMA probe 2770 (FIGURE 28) is provided for single-mode operation, such as transmitting or receiving beams.
  • the SMA probe 2770 includes, for delivering EM energy to or from the antenna 2700, an outer conductor 2772 which is electrically connected to the ground plane 2716, and an inner (or feed) conductor 2774 which is electrically connected and centrally positioned along the transmission line 2726 for proper radiation. While it is preferable that the probe 2770 be an SMA probe, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the inner conductor 2774 and the center stripline 2726a, and an appropriate seal (not shown) may be provided where the SMA probe 2770 passes through the ground plane 2716 to hermetically seal the connection.
  • the other end of the SMA probe 2770 not connected to the antenna 2700, is connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 2700 may be used for transmitting or receiving linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the incoming signal travels as a traveling wave along the transmission line 2726 through the first portions 2726a, the second portions 2726b, which behave as a quarter- wavelength transformer, and then through further quarter- wavelength transformers and power dividers to transport the EM power ultimately to striplines 2724 with minimal reflection and relatively uniform power distribution among the vertical striplines 2724.
  • the EM power is transmitted through the striplines 2724 to the array of patches 2720.
  • the patches 2720 then induce a high-order standing wave for proper radiation through the radiating edges 2720b of each patch 2720 of the antenna 2700. It is well known that antennas transmit and receive signals reciprocally.
  • the antenna 2700 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 2700 is so directed by orienting the top surface 2712b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 2700 are correctly sized for receiving the beam, then the beam will pass through the apertures 2750 and induce a standing wave that will resonate within the resonant cavity of the array of patches 2720 in the dielectric layer 2712.
  • a standing wave induced in the resonant cavity defined in the dielectric layer 2712 leaks EM power through the transmission line network comprising the striplines 2724 and 2726 to the SMA probe 2770, and is delivered to a receiver, such as a decoder (not shown) .
  • a receiver such as a decoder (not shown) .
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 2700 for transmitting signals is reciprocally identical to that of the antenna for receiving signals. The transmission of signals by the antenna 2700 will, therefore, not be further described herein. It is understood that the present invention can take many forms and embodiments. The embodiments described with respect to FIGURES 27 and 28 are intended to illustrate rather than to limit the invention.
  • FIGURES 29-31 Referring to FIGURES 29A and 29B (hereinafter "FIGURE 29") and FIGURE 30, the reference numeral 2900 designates, in general, a planar microstrip array antenna embodying features of the present invention for dual-mode operation, such as transmitting or receiving beams.
  • the antenna 2900 includes a generally square, dielectric layer 2912.
  • the width 2902 and length 2903 of the layer 2912 may be equal or unequal, and are determined by the number of patches used, discussed below, and, preferably, extends a width and length 2902a of at least 0.50 ⁇ ⁇ beyond the outer edges of patches 2920.
  • the dielectric layer 2912 defines a bottom side 2912a to which a conductive ground plane 2916 is bonded, and a top side 2912b to which an array of conductive radiating patches 2920 (FIGURE 29) are bonded for forming a resonant cavity within the dielectric layer 2912, between the ground plane 2916 and the patches 2920 and striplines 2924.
  • the patches 2920 are generally square in shape, having four corners 2920a and four radiating edges 2920b, each having a length 2920c of about 0.5 ⁇ ⁇ .
  • the patches 2920 are electrically interconnected via two, three or four corners 2920a to an array of substantially horizontal and vertical conductive striplines 2924, which are bonded to the dielectric layer 2912.
  • the striplines 2924 are in turn electrically interconnected via a substantially horizontal conductive transmission line 2926 and a substantially vertical conductive transmission line 2928.
  • the transmission lines 2926 and 2928 are bonded to the dielectric layer 2912, and the intersection of the transmission lines 2926 and 2928 is denoted in FIG.
  • each stripline 2924 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • the transmission lines 2926 and 2928 include first portions 2926a and 2928a, respectively, preferably configured to have a characteristic impedance of about 100 ohms for an input impedance of about 50 ohms, with a feed line 2974 positioned on each of the transmission lines 2926 and 2928, as discussed below with respect to the SMA probe 2970, to ensure proper radiation.
  • Each of the transmission lines 2926 and 2928 further includes two second portions 2926b and 2928b, respectively, preferably configured as quarter-wavelength transformers to have minimal reflection.
  • FIGURE 30 depicts one preferred configuration wherein the transmission lines 2926 and 2928 may intersect at the dashed outline 2927 without electrical contact.
  • the transmission line 2928 includes a bridge comprising two vias 2928c by which it passes under the transmission line 2926, wherein the two vias 2928c pass through openings in the ground plane 2916 without electrically contacting the ground plane 2916, and which in turn are electrically connected by a microstrip 2928d (FIGURE 31) which is electrically insulated from the ground plane 2916 via a dielectric 2913.
  • the non-conductive intersection of the transmission lines 2926 and 2928 may be achieved by using a directional coupler, described below with respect to FIGS. 31 and 32.
  • the dimensions of the patches 2920, the transmission lines ' 2924 and 2926, the apertures 2950, and the center-to-center spacing 2960 are individually calculated so that a high- order standing wave is generated in the antenna cavity formed within the dielectric 2912, and so that fields radiated from the radiating edges 2920b interfere constructively with one another.
  • the number of patches 2920 determines not only the overall size, but also the directivity, of the antenna 2900.
  • the sidelobe levels of the antenna 2900 are determined by the field distribution among the radiating elements 2920. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the size and the position of each of the patches 2920 and the feeding scheme.
  • the field distribution among the radiating elements 2920 is assumed to be as uniform as possible.
  • one or more shortening pins may be disposed in the antenna 2900 electrically connecting together the ground plane, patches, and/or striplines to suppress unwanted mode excitations.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Anasoft Corp., and will, therefore, not be discussed in further detail herein.
  • Each SMA probe 2970 includes, for delivering EM energy to or from the antenna 2900, an outer conductor 2972 which is electrically connected to the ground plane 2916, and an inner (or feed line) conductor 2974 which is electrically connected and positioned along the transmission lines 2926 and 2928 to optimize the impedance matching of the antenna 2900.
  • the feed lines 2974 are spaced a distance 2975 of about a quarter- wavelength plus multiple of ⁇ ⁇ off-center from where the transmission lines 2926 and 2928 intersect, as indicated within dashed outline 2927 (FIGURE 29) .
  • the probes 2970 be SMA probes
  • any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between the feed line 2974 and the center stripline 2926a, and an appropriate seal (not shown) may be provided where the SMA probe 2970 passes through the ground plane 2916 to hermetically seal the connection.
  • the other end of the SMA probe 2970, not connected to the antenna 2900 is connectable via a cable (not shown) to a signal generator or to a receiver such as a satellite signal decoder used with television signals.
  • the antenna 2900 may be used for transmitting and/or receiving linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the incoming signal travels as a traveling wave along the transmission lines 2926 and 2928 through the first portions 2926a and 2928a, respectively, to transport the EM power to the two branches 2926b and 2928b and subsequently striplines 2924 with minimal reflection.
  • the EM power is transmitted through the striplines 2924 to the array of patches 2920.
  • the patches 2920 and portions of the striplines 2924 then induce a high-order standing wave for proper radiation through the apertures 2950 of the antenna 2900.
  • the vertical modal excitation becomes orthogonal to that of the horizontal mode so that the cross talk between the two input signals will be minimized.
  • two orthogonal vertical and horizontal modes can be excited independently.
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 2900 for transmitting signals is reciprocally identical to that of the antenna for receiving signals.
  • the antenna 2900 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 2900 is so directed by orienting the top surface 2912b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 2900 are correctly sized for receiving the beam, then the beam will pass through the apertures 2950 and induce a standing wave that will resonate within the resonant cavity in the dielectric layer 2912 between the array of patches 2920 and the striplines 2924 and the ground plane 2916. A standing wave induced in the resonant cavity defined in the dielectric layer 2912 is transmitted through the transmission line network comprising the striplines 2924 and 2926 to the SMA probes 2970 and is delivered to a receiver, such as a decoder (not shown) .
  • a receiver such as a decoder
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 2900 for transmitting signals is reciprocally identical to that of the antenna for receiving signals. The transmission of signals by the antenna 2900 will, therefore, not be further described herein. It is understood that the present invention can take many forms and embodiments. The embodiments described with respect to FIGURES 29 and 30 are intended to illustrate rather than to limit the invention. Accordingly, several variations may be made in the foregoing without departing from the spirit or the scope of the invention. For example, additional patches 2920 may be provided for narrowing a beam, or fewer patches 2920 may be utilized to reduce the physical space required for the antenna 2900 of the present invention.
  • FIGURES 32-33 Referring to FIGURES 32 and 33, the reference numeral 3200 designates, in general, a planar microstrip array antenna embodying features of the present invention for dual-mode operation, such as transmitting and receiving beams.
  • the antenna 3200 includes a generally square, dielectric layer 3212.
  • the width 3202 and length 3203 are generally square, dielectric layer 3212.
  • the dielectric layer 3212 defines a bottom side 3212a to which a conductive ground plane 3216 is bonded, and a top side 3212b to which an array of conductive radiating patches 3220 are bonded for forming a resonant cavity within the dielectric layer 3212, between the patches 3220, the striplines 3224 and 3226, and the ground plane 3216.
  • the patches 3220 are generally square in shape, having four corners 3220a and four radiating edges 3220b, each having a length 3220c of about 0.5 ⁇ ⁇ .
  • the patches 3220 are electrically interconnected via corners 3220a to an array of substantially vertical conductive striplines 3224 and horizontal conductive striplines 3226.
  • the striplines 3224 and 3226 are electrically interconnected via respective transmission lines 3224a, 3224b, 3226a, and 3226b to a directional coupling 3400, described in further detail below with respect to FIGURE 34, for communicating EM energy with a probe, described in further detail with respect to the SMA probes 3270.
  • the striplines 3224, 3226, and transmission lines 3224a, 3224b, 3226a, and 3226b are bonded to the dielectric layer 3212.
  • the patches 3220 are spaced apart by a center-to-center distance 3260 of preferably about 1 ⁇ ⁇ .
  • the patches 3220 are preferably arranged in four sub-arrays and, within each sub-array, into a plurality of rows and columns on the top surface 3212b, representatively exemplified in dashed outlines by a sub-array 3222 having rows 3228 and columns 3229 offset from each other.
  • the width of each stripline 3224 and 3226 is preferably determined assuming a characteristic impedance of about 50 to 200 ohms.
  • the transmission lines 3224a and 3226a are preferably configured to have a characteristic impedance of about 100 ohms for an input impedance of about 50 ohms, with a feed line positioned on the striplines 3224 and 3226, as discussed below with respect to the SMA probes 3270, to ensure a proper phase for each stripline and patch so that an optimum gain results.
  • the transmission lines 3224b and 3226b are preferably configured as two quarter-wavelength transformers in series to have minimal reflection.
  • the dimensions of the patches 3220, the striplines 3224, 3226, and the apertures 3250, the center-to-center spacing 3260, and the coupler 3100 are individually calculated so that a high-order standing wave is generated in the antenna cavity formed by the dielectric 3212, and so that fields radiated from the radiating edges 3220b interfere constructively with one another.
  • the number of patches 3220 determines not only the overall size, but also the directivity, of the antenna 3200.
  • the sidelobe levels of the antenna 3200 are determined by the field distribution among the radiating elements 3220. Therefore, antenna characteristics, such as directivity and sidelobe levels, are controlled by the size and the position of each of the patches 3220 and the feeding scheme.
  • the field distribution among the radiating elements 3220 is assumed to be as uniform as possible.
  • one or more shortening pins may be disposed in the antenna 3200 electrically connecting together the ground plane, patches, and/or striplines to suppress unwanted mode excitations.
  • the foregoing calculations and analysis utilize techniques, such as the cavity model, discussed, for example, by Lee and Hsieh, and the moment method, discussed, for example, in the software EnsembleTM available from Anasoft Corp., and will, therefore, not be discussed in further detail herein.
  • Each SMA probe 3270 includes, for delivering EM energy to and/or from the antenna 3200, an outer conductor 3272 which is electrically connected to the ground plane 3216, and an inner (or feed) conductor 3274 which is electrically connected to and positioned along a respective transmission line 3224a or 3226a to ensure a proper phase for each stripline and patch so that an optimum gain results. While it is preferable that the probes 3270 be SMA probes, any suitable coaxial probe and/or connection arrangement may be used to implement the foregoing connections.
  • a conductive adhesive (not shown) may be used to bond and maintain contact between an inner conductor 3274 and the transmission line 3224a, and an appropriate seal (not shown) may be provided where the SMA probe 3270 passes through the ground plane 3216 to hermetically seal the connection. It is understood that the other end of the SMA probes 3270, not connected to the antenna 3200, are connectable via a cable (not shown) to a signal generator or to a receiver, such as a satellite signal decoder used with television signals.
  • the antenna 3200 may be used for transmitting and receiving linearly polarized (LP) EM beams.
  • LP linearly polarized
  • the incoming signal travels as a traveling wave along the transmission line 3224a through the coupler 3400 to the opposing transmission line 3224a.
  • the transmission line 3224a transports the EM power of the signal to the two branch transmission lines 3224b and, subsequently, striplines 3224 of each branch transmission line 3224b with minimal reflection.
  • the EM power is transmitted through the striplines 3224 to the array of patches 3220.
  • the patches 3220 and portions of the striplines 3224 then induce a high-order standing wave for proper radiation through the apertures 3250 of the antenna 3200.
  • the incoming signal travels as a traveling wave along the transmission line 3226a through the coupler 3400 to the opposing transmission line 3226a.
  • the transmission line 3226a transports the EM power of the signal to the two branch transmission lines 3226b and, subsequently, striplines 3226 of each branch transmission line 3226b with minimal reflection.
  • the EM power is transmitted through the striplines 3226 to the array of patches 3220.
  • the patches 3220 then induce a high-order standing wave for proper radiation through the apertures 3250 of the antenna 3200.
  • the vertical modal excitation becomes orthogonal to that of the horizontal mode so that the cross-talk between the two input signals will be minimized.
  • two orthogonal vertical and horizontal modes can be excited independently.
  • antennas transmit and receive signals reciprocally. It can be appreciated, therefore, that operation of the antenna 3200 for transmitting signals is reciprocally identical to that of the antenna for receiving signals.
  • the antenna 3200 may be positioned in a residential home and directed for receiving from a geostationary, or equatorial, satellite a beam carrying a television signal within a predetermined frequency band or channel.
  • the antenna 3200 is so directed by orienting the top surface 3212b toward the source of the beam so that it is generally perpendicular to the direction of the beam. Assuming that the elements of the antenna 3200 are correctly sized for receiving the beam, then the beam will pass through the apertures 3250 and induce a standing wave that will resonate within the dielectric layer 3212. A standing wave induced in the resonant cavity defined within the dielectric layer 3212 leaks electromagnetic power through the striplines 3224 and 3226 and coupler 3400 to the appropriate SMA probe 3270 and delivered to a receiver, such as a decoder (not shown) . It is understood that the present invention can take many forms and embodiments. The embodiments described with respect to FIGURES 32 and 33 are intended to illustrate rather than to limit the invention.
  • FIGURES 34-35 Referring to FIGURE 34, the reference numeral 3400 designates, in general, a planar microstrip directional coupler embodying features of the present invention for coupling two EM energy sources to two EM energy destinations, so that EM energy may be communicated to/from the two sources from/to the two destinations without interference.
  • the coupler 3400 is preferably integrated into a microstrip antenna, such as the antenna 2900 and the antenna 3200.
  • the coupler 3400 may also function as a standalone coupler, as shown in FIGURE 34, and, for the sake of simplicity, will be so described herein.
  • the coupler 3400 includes a generally square, dielectric layer 3412.
  • the dielectric layer 3412 has a width 3402 and length 3403 which may be equal or unequal.
  • the dielectric layer 3412 defines a bottom side 3412a to which a conductive ground plane 3416 may optionally be bonded and a top side 3412b to which an array of conductive striplines are bonded for forming the directional coupler.
  • the striplines include first striplines 3420 and 3422, between which EM energy is transferred, and second striplines 3424 and 3426, between which EM energy is transferred.
  • the width of each stripline 4124 is preferably determined assuming a characteristic impedance Z 0 of about 50 to 200 ohms.
  • the striplines 3420, 3422, 3424, and 3426 are connected to a substantially rectangular bridge 3430 having, as viewed in FIGURE 34, two end portions 3432, top and bottom portions 3434, and a mid-section portion 3432.
  • the width of each end portion 3432 is determined assuming a characteristic impedance Z 0 of about 50 to 200 ohms, and the length 3432a of each end portion 3432 is about 0.25 ⁇ ⁇ .
  • each top and bottom portion 3434 is determined assuming a characteristic impedance Z 0 / (square root of 2) of about 35 to 141 ohms, and the length 3434a of each half of each end portion 3432 is about 0.25 ⁇ ⁇ .
  • Each top and bottom portion 3434 is further characterized by an end 3434b chamfered at an angle of about 45°, relative to the top and bottom portions.
  • the width of the mid-section portion 3436 is determined assuming a characteristic impedance Z 0 /2 of about 25 to 100 ohms.
  • EM energy on the stripline 2928a is passed from the stripline 3420 to the stripline 3422 (or from the stripline 3422 to the stripline 3420) with substantially negligible loss to the striplines 3424 and 3426.
  • EM energy on the stripline 2926a passes from the stripline 3424 to the stripline 3426 (or from the stripline 3426 to the stripline 3424) with substantially negligible loss to the striplines 3420 and 3422.
  • any of the aforementioned antennas, configured for operation at one frequency may be reconfigured for operation at substantially any other desired frequency without significantly altering characteristics, such as the radiation pattern and efficiency of the antenna at the one frequency, by generally scaling each dimension of the antenna in direct proportion to the ratio of the desired frequency to the one frequency, provided that the dielectric constant of the dielectric layers remains substantially the same at the desired frequency as at the one frequency.

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  • Waveguide Aerials (AREA)
  • Variable-Direction Aerials And Aerial Arrays (AREA)

Abstract

L'invention porte sur une antenne à microbandes qui possède une couche unique de diélectrique sur une face de laquelle est disposé un plan de masse conducteur, et sur l'autre face de la couche diélectrique est disposé un réseau de plaques rayonnantes espacées. Les plaques rayonnantes sont interconnectées par une borne d'alimentation par l'intermédiaire d'éléments de lignes rubans. En réaction à l'énergie électromagnétique, une onde stationnaire d'ordre élevé est induite dans l'antenne et un faisceau dirigé est transmis depuis l'antenne et/ou reçu dans celle-ci. Une forme d'exécution bimodale est configurée de sorte que les noeuds de l'onde stationnaire apparaissent à l'intersection des lignes rubans orthogonales afin de minimiser les intensités des signaux à polarisation croisée et la diaphonie entre les deux modes de fonctionnement.
EP04750275A 2004-04-19 2004-04-19 Antenne reseau a microbandes Withdrawn EP1741160A1 (fr)

Applications Claiming Priority (1)

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PCT/US2004/011934 WO2005114792A1 (fr) 2004-04-19 2004-04-19 Antenne reseau a microbandes

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US8743016B2 (en) * 2010-09-16 2014-06-03 Toyota Motor Engineering & Manufacturing North America, Inc. Antenna with tapered array
CN105425322B (zh) * 2015-11-19 2017-06-16 华中科技大学 一种全光波长转换器
CN108352620B (zh) * 2015-11-27 2021-10-26 日立金属株式会社 天线装置
US10892550B2 (en) * 2016-06-16 2021-01-12 Sony Corporation Cross-shaped antenna array
EP3787112A1 (fr) * 2019-09-02 2021-03-03 Nokia Solutions and Networks Oy Réseau d'antennes polarisées
CN114498011B (zh) * 2021-12-29 2023-12-15 中电科创智联(武汉)有限责任公司 一种高性能微带阵列天线

Family Cites Families (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3987455A (en) * 1975-10-20 1976-10-19 Minnesota Mining And Manufacturing Company Microstrip antenna
US4180817A (en) * 1976-05-04 1979-12-25 Ball Corporation Serially connected microstrip antenna array
GB1529541A (en) * 1977-02-11 1978-10-25 Philips Electronic Associated Microwave antenna
US4605931A (en) * 1984-09-14 1986-08-12 The Singer Company Crossover traveling wave feed for microstrip antenna array
FR2622055B1 (fr) * 1987-09-09 1990-04-13 Bretagne Ctre Regl Innova Tran Antenne plaque microonde, notamment pour radar doppler
US5233361A (en) * 1989-09-19 1993-08-03 U.S. Philips Corporation Planar high-frequency aerial for circular polarization
FR2667730B1 (fr) * 1990-10-03 1993-07-02 Bretagne Ctre Rgl Tra Antenne.
FR2799580B1 (fr) * 1999-10-12 2007-12-28 Univ Rennes Antenne imprimee a bande passante elargie et faible niveau de polarisation croisee, et reseau d'antennes correspondant
US7705782B2 (en) * 2002-10-23 2010-04-27 Southern Methodist University Microstrip array antenna

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
See references of WO2005114792A1 *

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WO2005114792A1 (fr) 2005-12-01
CN1985406A (zh) 2007-06-20

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