Abstract:
The present invention features a dual mode, meander line loaded antenna (MLA) having an additional wideband plate or hat located above the horizontal top surface of the MLA antenna. The upper plate is spaced a predetermined distance above the MLA and held in place by dielectric blocks of a predetermined thickness. By properly spacing the additional plate, simultaneous wideband and narrowband reception can be performed. The added upper plate generally does not interfere with the usual narrowband operation of the original antenna structure. The modified antenna can accept radio frequency signals across a wide range of frequencies. The additional upper plate can be retrofitted to existing MLAs to modify them for dual mode operation.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS  
       [0001]    This application claims priority to U.S. Provisional Patent Application Serial No. 60/211,429, filed Jun. 14, 2000. This application is also related to previously issued U.S. Pat. No. 5,790,080 for a MEANDER LINE LOADED ANTENNA, which is hereby incorporated by reference. 
     
    
     
       FIELD OF THE INVENTION  
         [0002]    This invention pertains to the field of antennas and, more particularly, to a dual mode meander line loaded antenna (MLA) providing simultaneous dual wideband and narrowband operation.  
         BACKGROUND OF THE INVENTION  
         [0003]    Existing MLA antennas are typically narrow band antennas. For many narrowband military and commercial applications, radio frequency signals can appear unexpectedly across a wide frequency range. These existing MLA antennas are not capable of working effectively in such an environment.  
           [0004]    In the prior art, efficient antennas have typically required structures with minimum dimensions on the order of a quarter wavelength of their intended radiating frequency. These dimensions allowed the antennas to be easily excited and to be operated at or near their resonance, limiting the energy dissipated in resistive losses and maximizing the transmitted energy. These antennas tended to be large in size at their resonant wavelengths. Further, as the operating frequency decreased, the antenna&#39;s dimensions were increased proportionally. In order to address the shortcomings of traditional antenna design and functionality, the meander line loaded antenna (MLA) was developed. The basic theory and design of the meander line loaded antenna is presented in U.S. Pat. No. 5,790,080.  
           [0005]    An example of a basic prior art MLA, also termed a varied impedance transmission line antenna, is shown in FIG. 1. The antenna  100  consists of two vertical sections (i.e., plates)  102  and a horizontal section  104 . The vertical and horizontal sections  102 ,  104 , respectively, are separated by gaps  106 . Also part of the antenna  100  are the meander lines  200  (FIG. 2), which are typically connected between the vertical and horizontal sections  102 ,  104  at the gaps  106 .  
           [0006]    The meander line  200  is designed to adjust the electrical (i.e., resonant) length of the antenna  100 . The design of the meander slow wave structure  200  is such that it is possible to switch lengths of the meander line  200  in or out of the circuit quickly and with negligible loss, in order to change the effective electrical length of the antenna  100 . This switching is possible because the active switching devices (not shown) are always located in the high impedance sections of the meander line  200 . This keeps the current through the switching devices (not shown) low and results in very low dissipation losses in the switches, thereby maintaining high antenna efficiency. Switching of sections of a meander line using mechanical, electrical, microelectromechanical systems (MEMS) switches, or the like, are well known to those skilled in the antenna design arts.  
           [0007]    The basic antenna of FIG. 1 can be operated in a loop mode that provides a “figure eight” coverage (i.e., radiation) pattern. Horizontal polarization, loop mode, is obtained when the antenna is operated at a frequency such that the electrical length of the entire line including the meander lines  200  is a multiple of full wavelength as shown in FIG. 3C.  
           [0008]    The antenna can also be operated in a vertically polarized mode, monopole mode, by adjusting the electrical length to an odd multiple of a half wavelength at the operating frequency, FIGS. 3B and 3D, respectively. The meander lines  200  can be tuned using electrical or mechanical switches (not shown) to change the mode of operation at a given frequency or to switch frequencies using a given mode.  
           [0009]    The meander line loaded antenna allowed the physical antenna dimensions to be significantly reduced in size while maintaining electrical lengths that were still multiples of a quarter wavelength. Antennas and radiating structures built using this design approach operate in the region where the limitation on their fundamental performance is governed by the Chu-Harrington relation:  
           Efficiency=FV 2 Q  
           [0010]    where: Q=Quality Factor;  
           [0011]    V 2 =Volume of the structure in cubic wavelengths; and  
           [0012]    F=Geometric Form Factor (F=64 for a cube or a sphere)  
           [0013]    Meander line loaded antennas achieve the efficiency limit of the Chu-Harrington relation while allowing the antenna size to be much smaller than a wavelength at the frequency of operation. Height reductions of 10 to 1 over quarter wave monopole antennas can be realized, while achieving comparable gain.  
           [0014]    But, the existing MLA antennas are narrowband antennas. For many narrowband military and commercial applications where signals can appear unexpectedly across a wide frequency range, the existing MLA antennas are not desirable.  
         DISCUSSION OF THE RELATED ART  
         [0015]    U.S. Pat. No. 5,790,080 entitled MEANDER LINE LOADED ANTENNA, describes an antenna that includes one or more conductive elements for acting as radiating antenna elements, and a slow wave meander line adapted to couple electrical signals between the conductive elements. The meander line has an effective electrical length that affects the electrical length and operating characteristics of the antenna. The electrical length and operating mode of the antenna may be readily controlled.  
           [0016]    U.S. Pat. No. 6,034,637 entitled DOUBLE RESONANT WIDEBAND PATCH ANTENNA AND METHOD OF FORMING SAME, describes a double resonant wideband patch antenna that includes a planar resonator forming a substantially trapezoidal shape having a non-parallel edge for providing a substantially wide bandwidth. A feed line ( 107 ) extends parallel to the non-parallel edge for coupling while a ground plane extends beneath the planar resonator for increasing radiation efficiency.  
           [0017]    U.S. Pat. No. 6,008,762 entitled FOLDED QUARTER-WAVE PATCH ANTENNA, describes a folded quarter-wave patch antenna which includes a conductor plate having first and second spaced apart arms. A ground plane is separated from the conductor plate by a dielectric substrate that is approximately parallel to the conductor plate. The ground plane is electrically connected to the first arm at one end and a signal unit is electrically coupled to the first arm. The signal unit transmits and/or receives signals having a selected frequency band. The folded quarter-wave patch antenna can also act as a dual frequency band antenna. In dual frequency band operation, the signal unit provides the antenna with a first signal of a first frequency band and a second signal of a second frequency band.  
           [0018]    Each antenna of the prior art devices requires the use of multiple, separate wideband and narrowband antennas. What is needed is a means to provide a wideband receive capability, while simultaneously receiving narrowband signals on the same MLA antenna. Such an antenna should be simple and inexpensive to manufacture and also enable retrofitting of existing MLA antennas.  
         SUMMARY OF THE INVENTION  
         [0019]    In accordance with the present invention, there is provided a dual mode, meander line loaded antenna (MLA) having an additional wideband plate or hat located above the horizontal top surface of the antenna. The upper plate is spaced a predetermined distance above the MLA and held in place by dielectric blocks of a predetermined thickness. By properly spacing the additional plate, simultaneous wideband and narrowband reception can occur. The added upper plate generally does not interfere with the usual narrowband operation/reception of the original antenna structure. The modified antenna can accept radio frequency signals appearing unexpectedly across a wide range of frequencies. The additional upper plate can be retrofitted to existing meander line loaded antennas to modify them for dual mode operation. The narrowband/wideband dual mode antenna operates simultaneously a wideband signal and a narrowband signal.  
           [0020]    It is therefore an object of the invention to provide a MLA antenna capable of simultaneous dual mode operation. One of the facets of the invention is to insert a structure that does not effect the existing tunable high frequency MLA antenna usage. In one embodiment, the additional structure is placed a few inches above the horizontal MLA section. Using the voltage induced between the structure and the horizontal section as the input to a high impedance field effect transistor (FET), the incidence vertical electric fields are detected simultaneous with the normal narrowband operation of the MLA antenna.  
           [0021]    It is a further object of the invention to provide a MLA antenna where the simultaneous dual operating modes are a broadband and a narrowband mode of operation. It is another object of the invention to provide a MLA antenna suitable for use in environments where signals may appear unexpectedly over a wide range of frequencies. It is a still further object of the invention to provide a MLA antenna suitable for use in wideband signal acquisition applications, while simultaneously performing direction finding.  
           [0022]    Another object is a narrowband/wideband dual mode antenna comprising a meander line loaded antenna (MLA) having a pair of vertical sections disposed substantially perpendicular to a ground plane, one of the pair of vertical sections being electrically connected to the ground plane. There is a substantially horizontal top section disposed above and substantially perpendicular to the pair of vertical sections, each end of the top section being proximate one of the pair of vertical sections and separated therefrom by a gap. One or more meander line elements are proximate at least one of the gaps and operatively connected to one of the vertical sections and to the top section. A wideband plate is disposed a predetermined distance above and electrically isolated from the horizontal top section. And, there is a feed means for accepting a voltage induced between the wideband plate and the top section by an incoming signal.  
           [0023]    And another object is the narrowband/wideband dual mode antenna, wherein the feed means is a high impedance amplifier. Furthermore, wherein the high impedance amplifier is a field effect transistor (FET) having a gate, a drain, and a source, wherein the gate is connected to the wideband plate, the source is connected to the top section, and the drain is connected to the vertical section electrically connected to the ground plane.  
           [0024]    Yet a further object is the narrowband/wideband dual mode antenna wherein the electrical isolation between the wideband plate and the horizontal top section is provided by a dielectric material. In one embodiment there is at least one dielectric block, although other separating means are within the scope of the invention. The dielectric material can be any high-frequency dielectric material such as Teflon7, polyethylene, and phenolic.  
           [0025]    An additional object is the narrowband/wideband dual mode antenna wherein the meander line loaded antenna is a tunable, varied impedance transmission line. And, wherein the tunable, varied impedance transmission line comprises switching means for selectively connecting and disconnecting at least a portion of the transmission line.  
           [0026]    Another object is the narrowband/wideband dual mode antenna wherein the meander line is a printed circuit structure.  
           [0027]    And, an object includes the narrowband/wideband dual mode antenna wherein the meander line elements are electrically isolated from the horizontal top section by a dielectric material. And, the narrowband/wideband dual mode antenna further comprising at least one dielectric bar disposed between at least two of the structures, the ground plane, at least one of the pair of vertical sections, and the substantially horizontal top section. Further comprising fastening means for securing at least one dielectric bar to one of the structures, wherein the fastening means comprises at least one from the group of screw, bolt, and adhesive.  
           [0028]    An object of the invention is a method for operating dual bandwidths using a meander line loaded antenna (MLA), comprising the steps of providing an MLA having a pair of vertical sections disposed substantially perpendicular to a ground plane, one of the pair of vertical sections being electrically connected to the ground plane, with a substantially horizontal top section disposed above and substantially perpendicular to the pair of vertical sections, each end of the top section being proximate one of the pair of vertical sections and separated therefrom by a gap, and with one or more meander lines proximate at least one of the gaps and operatively connected to at least one of the vertical sections and to the top section. Disposing a wideband plate at a predetermined distance above and electrically isolated from the horizontal top section by at least one dielectric block, and securing the wideband hat to the dielectric block. Providing wideband feed means electrically connected to the horizontal top section and the wideband hat for accepting a voltage induced between the wideband hat and the horizontal top section by an incoming radio frequency signal, whereby the dual mode antenna receives simultaneous broadband and narrowband signals.  
           [0029]    And a further object is the method for operating dual bandwidths, further comprising the step of electrically connecting the vertical section connected to the feed means, wherein the connecting does not cross the gap.  
           [0030]    It is an additional object of the invention to provide a MLA antenna incorporating a wideband mode plate to allow simultaneous dual mode operation. It is another object of the invention to provide a MLA antenna having a wideband hat section that may be retrofitted to existing narrowband meander line loaded antennas.  
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0031]    A complete understanding of the present invention may be obtained by reference to the accompanying drawings, when considered in conjunction with the subsequent detailed description, in which:  
         [0032]    [0032]FIG. 1 is a schematic, perspective view of a simple MLA loop antenna of the prior art;  
         [0033]    [0033]FIG. 2 is a schematic, perspective view of a meander line structure suitable for use with the antenna of FIG. 1;  
         [0034]    FIGS.  3 A- 3 D are a series of comparative diagrams showing various possible operating modes of the antenna of FIG. 1;  
         [0035]    [0035]FIG. 4 is a cross-sectional, electrical schematic view of the inventive antenna showing the wideband plate of the invention; and  
         [0036]    [0036]FIG. 5 is a cross-sectional, schematic view of the inventive antenna showing the placement of dielectric material in the antenna structure.  
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT  
       [0037]    The present invention provides a dual-mode, meander line loaded (MLA) antenna capable of simultaneous broadband and a narrowband operating modes.  
         [0038]    Referring again to FIGS. 1 and 2, there are shown cross-sectional, schematic views of an MLA loop antenna  100  of the prior art (FIG. 1) and an associated variable impedance line section  200  (FIG. 2) suitable for use with the antenna  100 . The construction and operation of such antennas are detailed in U.S. Pat. No. 5,790,080.  
         [0039]    These existing MLA antennas are typically narrow band antennas. For many narrowband military and commercial applications, radio frequency signals can appear unexpectedly across a wide frequency range. These existing MLA antennas are not capable of working effectively in such an environment.  
         [0040]    The present invention provides an antenna assembly based on prior MLA antenna structures but which is capable of meeting the dual wideband/narrowband operating requirements of many applications. This provides an antenna having the capability to acquire signals over a wide frequency bandwidth while simultaneously receiving narrowband signals. The wideband (e.g., 2 MHz to 30 MHz) reception capability of the antenna of the present invention is created by adding a structure above a traditional meander line antenna that does not affect the existing tunable high frequency meander line antenna.  
         [0041]    Referring now to FIG. 4, there is shown a cross sectional, schematic view of the inventive antenna structure  400 . A typical MLA loop antenna  100  consisting of vertical sections  102 , horizontal section  106  and having gaps  106  bridged by meander lines  200 , is shown disposed above a ground plane  402 . A horizontal plate  404  is disposed substantially parallel and above the horizontal MLA section  104  at a spacing determined by the intended operating characteristics of the antenna. Distinguished from the prior art MLA, one of the vertical sides  102  is not connected to the ground plane as shown in FIG. 5. The feed  416  is illustrated to depict the signal that is produced by having the vertical side  102  in an ungrounded state.  
         [0042]    For example, based upon empirical data gathered from experimentation, a gap of approximately 3 inches has been shown effective for wideband operation in a range of frequencies between approximately 2 MHz and 30 MHz. In effect, the narrowband operation of the MLA, for example 100 KHz, now simultaneously has a wideband range due to the wideband cap of between, for example, 2 MHz and 30 MHz. This frequency band is merely illustrated as an example of one of the more commercially viable bands. This example is chosen for purposes of disclosure and it will be obvious to those skilled in the antenna design arts that other spacings could be chosen to meet a particular frequency band operating requirement. Furthermore, the narrowband signal can be tuned to any signal using the switching means discussed in the prior art.  
         [0043]    By using a voltage (shown schematically as voltage source  406  ) induced between the horizontal plate  404  and the horizontal section  104  of antenna  100  as the input to a high impedance amplifier (not shown) having an input impedance greater than about 1000 ohms, it is possible to detect incident vertical electronic fields (i.e., induced voltage  406  ) while not disturbing the normal narrowband operation of antenna  100 . The high impedance amplifier can be a field effect transistor (FET) device or the like. This single antenna having dual mode operating characteristics can replace a separate acquisition antenna.  
         [0044]    Simulations of the inventive antenna structure show that the efficiency of the wideband mode approaches the Chu limit, which is given by:  
         Efficiency=FV 2 Q  
         [0045]    where: Q=Quality Factor;  
         [0046]    V 2 =Volume of the structure in cubic wavelengths; and  
         [0047]    F=Geometric Form Factor (F=64 for a cube or a sphere)  
         [0048]    The gain of the antenna (dBI) can then be calculated by multiplying the directivity of the antenna by the efficiency. The results of the simulations for a 2 MHz to 30 MHz narrowband and wideband dual mode antenna with dimensions 12 inches×12 inches×36 inches are shown in Table 1 of the computer simulations. Both the narrowband gain and the wideband gain are illustrated.  
                                     TABLE 1                       Frequency   Wideband Gain   Narrowband Gain       [MHz]   [dBI]   [dBI]                                30   −15   +2       20   −21   −4       10   −30   −13       3   −45   −25                  
 
         [0049]    Referring now also to FIG. 5, there is shown a cross sectional view of the inventive antenna structure showing construction details thereof. One of the vertical radiating sections  102  are attached to the ground plane  402  and the other has a gap  420  separating the one vertical side  102  from the ground plane. Either side can have the gap or separation  420 . A pair of meander line antennas  200  are resident at the gaps  106  with connections to the vertical and horizontal sections  102 ,  104 . In this embodiment the MLA elements  200  are secured to a dielectric material  412 , which would normally be connected directly to the horizontal plate  104 . The embodiment shown in FIG. 5 has the dielectric substrate  412  separated from the horizontal plate  104  by one ore more spacers  422  that are spaced from the horizontal section  104  by spacers  422 , although spacers are not necessary. Furthermore, the dimensions of FIG. 5 are not representative of the actual dimensions of the various distances.  
         [0050]    In one embodiment, the high impedance amplifier  450  is connected via a coaxial cable  430 , preferably insulated, that runs from the grounded vertical side  102  around the structure and wound about the meander line  200 . The cable  430  electrically the Drain of a FET  450 , with the Gate connecting to the wideband plate  404  and the Source connecting to the horizontal top cover  104 . The coaxial cable  430  is snaked around the various elements to avoid jumping gaps that could de-tune the device and connects to the vertical side  102 .  
         [0051]    In one embodiment the vertical sections  102  are structurally interconnected by the use of rectangular bars of dielectric material  420 . The bars  420  maintain the shape and assist in keeping the separation  420  of the vertical side intact. Any high frequency dielectric material could be used, such as Teflon7, polyethylene and phenolic. Other suitable materials well known to those skilled in the antenna design arts could also be used. The sections  102 ,  104  are fastened to the dielectric bars  420  with screws, bolts, or other suitable fasteners (not shown), including adhesives and adhesive tapes.  
         [0052]    An optional additional bar  410  is located between the grounded vertical side  102  and ground plane  402 . The material used in the bar  410  may be either a dielectric or a conductor, because vertical side  102  is grounded to the ground plane  402 . For this attachment, welding or soldering would also provide a suitable attachment method. For all of the other attachments, the use of the dielectric  408  is useful to maintain the insulation of one section from another as well as the structural integrity. The dielectric used and the gap between the sections at these locations must be sufficient to prevent field breakdown at the field strengths for which the antenna is designed to operate.  
         [0053]    The meander lines  200  are attached to the top section  104  by means of rectangular dielectric spacer bars  420  and fasteners, such as screws or bolts (not shown) or other fasteners or adhesives. A sheet of dielectric material  412  is used to provide support for the meander line  200  while electrically isolating it from the section  104 . Attachment points for meander line  200  other than horizontal section  102  may be chosen if their location is more convenient for a particular implementation of the antenna.  
         [0054]    In alternate embodiments, meander line  200  could be manufactured from printed circuit board material and therefore be designed to attach directly to the top section  104  by soldering or using screws. In this approach, one side of the printed circuit board material would be in contact with the top section  104  and the other side of the printed circuit board would have parts of the meander line circuit etched into it. The board material itself would act as the dielectric insulator. Such printed circuit board technology is known in the art.  
         [0055]    In one embodiment, the wideband hat (wideband plate)  404  is attached to the top section of the antenna  100  by means of two rectangular bars of dielectric material  408 , as shown in FIG. 5, using screws or bolts (not shown) for fasteners. The substantially horizontal uppermost plate  404  forms a wideband hat that is excited by meander line antenna currents in the horizontal section  104 . This excitation gives rise to a potential difference  406  between the hat  404  and the horizontal section  104 . The induced waves can arise from vertically polarized waves induces a volt difference between the wideband plate and the top cover.  
         [0056]    The high input impedance amplifier  450  picks up the voltage  406  (FIGS. 4, 5). The amplifier&#39;s input impedance Z at the resonant frequency, f 0 , is given by:  
           Z= ( X   2   +R   2 ) 05    
         [0057]    Where: X=reactance  
         [0058]    R=resistance  
         [0059]    The reactance and the resistance of the antenna and can be used to design the antenna for optimal power transfer. The resonance frequency can be calculated by taking the geometric mean, for example the geometric mean of the 2-30 MHz range is about 24 MHz  
         [0060]    The antenna of the present invention provides several advantages over the antenna structures of the prior art. One advantage is that the inventive antenna occupies a relatively low volume. This, along with the instantaneous bandwidth for signal acquisition and the simultaneous narrowband reception capability, results in antenna performance unmatched in prior art antenna structures. As a result, fewer antennas are required. In airborne applications, fewer antennas results in a reduced radar cross section, always a desirable attribute. In installations where MLA antennas are already in place, the wideband capability can be retrofitted to these existing antennas.  
         [0061]    While the efficiency of the wideband antenna is relatively low, for signal acquisition, this is not a significant problem and the advantages of the inventive antenna more than compensate for this characteristic.  
         [0062]    Typical applications foreseen for the inventive antenna are commercial use for cell phone bands, PCS and PHS applications where there may be an economic advantage to having a wideband signal acquisition capability to detect new signals before assigning a narrowband channel to them. Presently, the main applications are likely to be on military platforms such as air or spacecraft.  
         [0063]    Since other modifications and changes varied to fit particular operating conditions and environments or designs will be apparent to those skilled in the art, the invention is not considered limited to the examples chosen for purposes of disclosure, and covers changes and modifications which do not constitute departures from the true scope of this invention.  
         [0064]    Having thus described the invention, what is desired to be protected by letters patents is presented in the subsequently appended claims.