Abstract:
A high impedance (Hi-Z) wire effectively transparent to electromagnetic radiation polarized in the direction of the wire, within an operating frequency band. The Hi-Z wire is sheathed with a thin layer of resonant structures that are small compared to the wavelength, and behave as a kind of photonic band gap (PBG) material. A frequency-selective polarizer comprising a plurality of Hi-Z wires disposed parallel to one other in a grid. A wire grid reflector that enables stepwise phase control of the reflected wave and focusing of radiative power, the reflector comprising Hi-Z wires interspersed with conventional wires disposed parallel to one another in a grid.

Description:
TECHNICAL FIELD 
     This invention relates to a high impedance (Hi-Z) wire that is effectively transparent to radiation polarized in the direction of the wire, within an operating frequency band. The wire is sheathed with a thin layer of resonant structures, forming a photonic band gap (PBG) material. Out of band frequencies are reflected by the wire, frequencies within the operating band are unaffected. Such wires are more physically rigid than dielectrics and can be applied to non-interactive antenna support stays, dispersive polarizing beam splitters, or wire grid reflectors for focusing radiative power. 
     BACKGROUND OF THE INVENTION 
     The assembly of PBG materials has recently been advanced at UCLA (University of California at Los Angeles) using printed circuit board techniques to make a two dimensional array of sub-wavelength scale resonant structures on the surface of the board. These concepts are referred to in U.S. patent application Ser. No. 09/537,923 entitled “A Tunable Impedance Surface” filed on Mar. 29, 2000 and U.S. patent application Ser. No. 09/525,255 entitled “Radio Frequency Aperture” filed on Mar. 14, 2000. 
     A conventional high-impedance surface, shown in FIG. 1, consists of an array of metal top plates or elements  13  on a flat metal sheet  12 . It can be fabricated using printed circuit board technology with the metal plates or elements  13  formed on a top or first surface of a printed circuit board and a solid conducting ground or back plane  12  formed on a bottom or second surface of the printed circuit board. Vertical connections are formed as metal plated vias  14  in the printed circuit board, which connect the elements  13  with the underlying ground plane  12 . The metal members, comprising the top plates  13  and the vias  14 , are arranged in a two-dimensional lattice of cells, and can be visualized as mushroom-shaped or thumbtack-shaped members protruding from the flat metal surface  12 . The top plates or elements  13  are preferably hexagonal and the thickness of the structure, which is controlled by the thickness of the printed circuit board, is much less than one wavelength for the frequencies of interest. The sizes of the elements  13  are also kept less than one wavelength for the frequencies of interest. The printed circuit board is not shown for ease of illustration. 
     Turning to FIG. 2, the properties of this surface can be explained using an effective circuit model which is assigned a surface impedance equal to that of a parallel resonant LC circuit. The use of lumped circuit elements to describe electromagnetic structures is valid when the wavelength is much longer than the size of the individual features, as is the case here. When an electromagnetic wave interacts with the surface of FIG. 1, it causes charges to build up on the ends of the top metal plates  13 . This process can be described as governed by an effective capacitance C. As the charges slosh back and forth, in response to a radio-frequency field, they flow around a long path P through the vias  14  and the bottom metal surface  12 . Associated with these currents is a magnetic field, and thus an inductance L. The capacitance C is controlled by the proximity of the adjacent metal plates  13  while the inductance L is controlled by the thickness of the structure. The structure is inductive below the resonance and capacitive above resonance. Near the resonance frequency          ω   =     1     LC         ,                          
     the structure exhibits high electromagnetic surface impedance. The tangential electric field at the surface is finite, while the tangential magnetic field is zero. Thus, electromagnetic waves are reflected without the phase reversal that occurs on a flat metal sheet. In general, the reflection phase can be 0, π, or anything in between, depending on the relationship between the test frequency and the resonance frequency of the structure. The reflection phase as a function of frequency, calculated using the effective medium model, is shown in FIG.  3 . Far below resonance, it behaves like an ordinary metal surface, and reflects with a π phase shift. Near resonance, where the surface impedance is high, the reflection phase crosses through zero. At higher frequencies, the phase approaches −π. The calculations are supported by the measured reflection phase, shown for an example structure in FIG.  4 . 
     It would be useful for numerous applications if it were possible to cover or coat a wire with a Hi-Z surface, so that the wire would behave like a Hi-Z structure. However, the structure of the Hi-Z surface, as described in the prior art, does not lend itself to such covering or coating of a wire. The present invention overcomes this difficulty and provides techniques for disposing Hi-Z surfaces on wires. A technique for electrically isolating a wire by modifying its behavior from a low resistance short to a highly reactive current path is provided. 
     Metal guy wires, stays or struts are often the preferred construction technique for stiffening mountings and long posts; or for suspending objects away from walls or ceilings. For microwave applications, for example for mounting a detector horn at the focus of a parabolic reflector, metal parts can be added that will not interfere with the desired propagation of the electromagnetic signal. The supports no longer need to be a source of interference. 
     The prior art includes RF reflector and focal plane sensor systems. Typically, satellite antennas deploy a detector at the focus of an offset parabolic reflector, such as with DirecTV™ or DirecPC®. The parabola is offset for reasons that involve beam blockage and diffraction by the supports. This invention enables other construction techniques with better overall performance. 
     Baluns (typically ferrite beads with high magnetic permeability or balun transformer cores) are sometimes slipped over a wire to induce a high inductive reactance for a lead. In effect it is a low pass filter. High frequencies are reflected or absorbed by losses in the balun. Thus, generally the balun&#39;s effect is used for blocking out of a band noise. The present invention has low loss and the frequency of operation is more controllable than that which can be achieved with magnetic materials. 
     The Hi-Z wire of the present invention can be applied to microwave polarizers. One conventional method of producing a microwave polarizer is to use a layer of thin wires spaced less than a wavelength apart and aligned in the same direction, thereby forming a grid. An incoming electromagnetic wave will have its electric field component parallel to the wires reflected, and its component orthogonal to the wires undeflected by the grid. When Hi-Z wires (i.e., covered with a PBG medium) are used in the grid, the polarization effect is frequency dependent, which makes the polarizer band selective. This feature provides a useful improvement over conventional microwave polarizers. 
     Hi-Z wires can be used to construct a Low/Hi-Z Fresnel reflector which improves on traditional Fresnel reflectors. By using an array of wires with spacing on the order of ½ wavelength, one can reflect a wave to various angles similar to a conventional grating. However, this configuration has low efficiency due to the wide spacing of the wires. By placing Hi-Z wires between the ordinary wires, the efficiency is significantly improved. This is only possible with Hi-Z wires. 
     BRIEF DESCRIPTION OF THE INVENTION 
     In accordance with this invention, a metal wire is sheathed with a thin layer of resonant structures, forming a Hi-Z (high impedance) wire that is effectively transparent to radiation polarized in the direction of the wire within an operating frequency band. These structures are small compared to a wavelength and can be fabricated in mass production. Since the wire sheathing is effectively a photonic band gap layer, out of band frequencies will be reflected by the wire. Hi-Z wires are more rigid than dielectrics, and can be applied to non-interacting antenna support stays. 
     In another aspect of this invention, Hi-Z wires are disposed parallel to one another in a grid to form a frequency-selective microwave polarizer. Outside a certain frequency band, the electric field component parallel to the wires is reflected by the polarizer, whereas the orthogonal component passes through unaffected. Within a certain frequency band, the wires appear transparent to the radiation and no polarization occurs. The polarizing effect is thus frequency selective. 
     In yet another aspect of the invention, Hi-Z wires are interspersed with conventional wires and disposed in a grid to form a Fresnel reflector. This configuration enables stepwise phase control of the reflected phase. 
     In yet another aspect of this invention, a method of sheathing a wire with a thin layer of resonant structures is provided, as well as a method of polarizing electromagnetic radiation. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 depicts a conventional high-impedance surface fabricated using printed circuit board technology of the type disclosed in U.S. Provisional Patent Ser. No. 60/079,953 and having metal plates on the top side connected through metal plated vias to a solid metal ground plane on the bottom side; 
     FIG. 2 is a circuit equivalent of a pair of adjacent metal top plates and associated vias; 
     FIG. 3 depicts the calculated reflection phase of the high-impedance surface of FIG. 1, obtained from the effective medium model and shows that the phase crosses through zero at the resonance frequency of the structure; 
     FIG. 4 shows that the measured reflection phase agrees well with the calculated reflection phase; 
     FIG. 5 shows a parabolic dish antenna the feed horn of which is mounted with Hi-Z wire supports; 
     FIGS. 6 a ,  6   b  and  6   c  depict a construction of the Hi-Z wire using C-shaped beads swaged on a wire; 
     FIGS. 7 a , 7   b  and  7   c  depict another construction of the Hi-Z wire using double-C-shaped beads swaged on a wire; 
     FIG. 8 a  is a cross-sectional view of the Hi-Z wire formed by a continuous extrusion and crimping method, and subsequent swaging of the extruded ribbed structures after conformal dielectric coating; 
     FIG. 8 b  is an external view of a coaxial cable sheathed with a Hi-Z layer according to the method of FIG. 8 a;    
     FIG. 8 c  is an external view of a coaxial cable sheathed with a Hi-Z layer by wrapping a continuous spiral strip around the cable; 
     FIG. 9 a  illustrates the extrusion and crimping method applied to a spiral screw structure, before swaging of the extruded ribs, and after coating with a conformal dielectric; 
     FIG. 9 b  shows the Hi-Z wire of FIG. 9 a , after swaging of the extruded spiral ribs; 
     FIG. 10 illustrates a tunable Hi-Z wire wrapped with two spiral layers, one being fixed and the other sliding along the direction of the wire for varying the capacitance. 
     FIG. 11 a  depicts a conventional wire grid polarizer; 
     FIG. 11 b  shows a band-selective Hi-Z wire grid polarizer; 
     FIG. 11 c  illustrates a Low/Hi-Z Fresnel reflector for low grating lobes. The reflector is formed of alternating Hi-Z and conventional wires; 
     FIG. 11 d  depicts the interaction, at resonance, of an incident wave with the reflector of FIG. 11 c,    
     FIG. 11 e  shows how the reflection/transmission angle can be tuned by either tuning the frequency of the incident wave, or tuning the resonance frequency of the Hi-Z wires. 
     FIG. 11 f  shows the use of a ground plane with the reflector of FIG. 11 c , which has the effect of eliminating the transmitted component of the wave. 
     FIG. 11 g  illustrates how the incident wave can be mostly reflected in one preferred direction, by varying the spacing between the wires. 
     FIGS. 12 a  and  12   b  show the interaction of the Hi-Z wire with an incoming plane wave, at a frequency below or above resonance (FIG. 12 a ) and at the resonant frequency (FIG. 12 b ); 
     FIGS. 13 a  and  13   b  illustrate the structure of the Hi-Z wire which is the object the computer simulation depicted in FIG. 13 c;    
     FIG. 13 c  shows one period of a simulated Hi-Z wire illuminated with a plane wave at a frequency near resonance. The small cavities in the wire support a mode which allows the plane wave to pass through the wire unaffected; 
     FIG. 14 a  is a graph showing the magnitude of the reflected and transmitted electric field as a function of frequency during the simulation of FIG.  13 . The reflection magnitude goes to zero near resonance where the wire appears transparent; and 
     FIG. 14 b  is a graph showing the phase of the reflected and transmitted electric field as a function of frequency during the simulation of FIG.  13 . The transmission magnitude crosses through zero at resonance where the wire appears transparent. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     FIG. 5 shows a possible application of the invention, where high impedance (Hi-Z) wires  1  are used to support the feed  2  of a conventional parabolic dish antenna  3 . The use of Hi-Z wires  1  minimizes the unwanted interactions of the incoming electromagnetic field with the wires  1  which support the feed  2 . A small diameter coaxial or fiber-optic lead  4  can be fabricated to run down the center of the Hi-Z wire  1 , thereby isolating the lead from the incoming radiation. 
     FIGS. 6 a ,  6   b ,  6   c  show a possible construction of the Hi-Z wire  1 , using C-shaped toroidal beads  10 . More specifically, each bead consist of a toroid with a C-shaped cross section  19  as can be seen in FIG. 6 a . A toroid is the surface defined by rotating a plane contour about an axis which lies in the same plane as the plane contour and which does not intersect the plane contour. In the particular case of FIG. 6, the plane contour has the shape of a C, which gives a C-shaped section to the toroidal bead. The beads  10  are preferably deep-die pressed out of a sheet metal which may include brass and/or copper, and threaded onto a wire  11 . The resonance frequency that characterizes the transition from low to high impedance is determined by the resonance frequency of the cavity formed by the adjacent beads. The inductive component Lo is set by the ratio of the inner and outer radii r 1  and r 2  respectively of the cavity and the cavity length L, Lo˜μ 0 L log(r 2 /r 1 ). The capacitance, C, is set by the area of the adjacent flange (area˜2πrΔr), and the spacing d between beads, C˜2πεrΔr/d. Consequently the transition frequency is near ω= 1/{square root over (2πεμ 0 L log(r2/r1)rΔr/d)}. For the case where r1= ½r 2 , r=¾r 2 , Δr=¼r, d=0.1r, ε=ε 0  and L=r 2 , we obtain: 
     ω=5.2 10 7 /r 1  rad/s and r 1 /λ=0.028. 
     This confirms that the overall diameter of the Hi-Z wire, D˜4 r 1 ˜0.112λ, can be made to be less than a tenth of a wavelength of the signal. 
     An alternative construction is shown in FIGS. 7 a ,  7   b ,  7   c . The resonant cavity is composed of two over-lapping C-shaped beads  15  and  16 , one bead  16  slightly smaller in diameter than the other bead  15 . The inner rim  32  of the bead  15  is secured to the inner rim  33  of the bead  16 , such that the open faces of the two beads face one another, thereby forming a double bead  17  as shown in FIG. 7 a . Beads  15  and  16  need to be conductively attached to one another. This can be done by brazing-coating them with tin, assembling them, and heating them. The bead  16  having a diameter which is smaller than the bead  15 , the outer rim  30  of bead  15  overlaps the outer rim  31  of bead  16 , thereby defining opposing plates of a capacitor. The capacitance of the capacitor thus formed depends on the area of overlap and the distance between the plates. The double beads  17  are threaded onto the wire  11  to form the Hi-Z wire  18  as shown in FIG. 7 c . Since the capacitance can be somewhat higher in this configuration, the relative diameter of the double beads  17  may be smaller than that of the single beads  10  shown in FIG. 6 a.    
     There is an advantage to not having discontinuities in the conductive path: reliability and reproducibility are maximized by conductive connections. In order to improve the conductivity of the single bead type, the joints of the assembly can be soldered, or brazed, or a conductive adhesive may be used. The double-C form shown in FIGS. 7 a,b,c  has the advantage that the primary resonance path is within the cavity where there is only one joint. This joint may be pre-soldered, welded, or brazed before assembly of the double C shaped beads  17  onto the wire. Alternately, the double-C shaped beads  17  may be constructed in one piece by a double-step deep-forming process. A conformal dielectric coating may be added between rims  30  and  31  and/or throughout the interior of the bead to enhance the capacitance and insure isolation of the capacitive gaps. As in the single bead case, when assembled onto the wire  11 , the double beads are preferably soldered or brazed in order to ensure a suitable conductive connection between the double beads. 
     Yet another embodiment is shown in FIGS. 8 a ,  8   b ,  8   c . FIG. 8 a  shows resonant sheathing structures  22  that may be formed by a continuous extrusion and crimping method out of thin tubing or sheet metal. A metal tube with metal ribs  20 , similar to a screw with very deep threads, is formed. The threads are coated with a conformal dielectric  21  , and then bent over so that they touch one another, with each layer lying on top of the next layer as shown in cross-section in FIG. 8 a . FIG. 8 b  shows how the sheathing might look when applied to a coaxial cable. FIG. 8 c  shows a spiral sheathing that is folded as it is applied in a continuous process by a spiral forming machine (as is done with flexible aluminum dryer vent hose). 
     Other similar configurations can be formed and applied to wires, such as tape-like wrappings. The tape may be composed of metal/dielectric composite film which is wrapped around a wire. 
     A preferred embodiment is to extrude the wire with twisted flat ribs  25  formed by a threading-like spiral surface wrapped around the core of the wire  27  as shown in FIG. 9 a . A conformal dielectric coating  26  is applied to both sides of the ribs  25  which are then swaged as shown in FIG. 9 b , to form the resonant cavities  28 . Rigidity and strength of the wire are provided by the central core  27 . 
     It is possible to construct variable overlaps in the capacitive parts of the C-shaped structures  10  and  17  shown in FIGS. 6 a ,  6   b ,  6   c  and  7   a ,  7   b ,  7   c . For example, this can be realized by stringing the beads on two wires and fixing alternating elements to each wire, one of which is a sliding wire; or by introducing variable dielectrics with voltage control activated through the wires. In this manner, the resonance frequency of the cavity can be varied, and the phase shift of this tunable Hi-Z wire can be independently controlled. Thus, an incoming wave of fixed frequency can be reflected at a desired angle. 
     Turning to FIG. 10, an example of a construction of the tunable Hi-Z wire is shown. A first spiral layer  47  is wrapped around the core  46  of the wire  49 . A second spiral layer  48  is wrapped around the first spiral layer  47  leaving a gap between the two spiral layers. A layer of dielectric can be introduced in the gap. The second spiral layer  48  can slide with respect to the first spiral layer  47 , the first spiral layer  47  being fixed to the core  46  of the wire. By sliding the second spiral layer  48  along the direction of the wire, the area of overlap of the two spiral layers can be varied, and therefore the capacitance of the structure can be changed. Since the capacitance of the structure is directly related to its resonance frequency, this embodiment provides a Hi-Z wire having a tunable resonant frequency. 
     Below or above resonance, and as illustrated in FIG. 12 a , the radiation  50  transmitted/reflected by the wire  45  is out of phase with the incoming signal  51 . The radiation  50  emitted from the wire  45  is roughly cylindrically symmetric and polarized with the electric field in the Z direction. Scattered radiation in the forward direction tends to cancel the signal wave in the forward direction, and the net reflected wave will peak in the backward propagating direction, as shown in FIG. 12 a . That is, the signal wave is back scattered as if the Hi-Z wire  45  were simply a solid wire. Thus, below or above resonance the Hi-Z wire  45  behaves like a simple wire. 
     As resonance is approached by increasing the frequency or tuning the Hi-Z wire, the wire current varies. The effective impedance of the wire exhibits a pole at the resonance frequency and its value goes to infinity. The wire current that couples to the signal wave then drops to zero, while its phase shifts by 90°. Consequently, the resonant field does not couple energetically to propagating waves, or scatter, and the wire appears transparent to the incoming wave  51 . The incoming wave  51 , passes through the wire unaffected. 
     Numerous structures and constructions thereof can be imagined and will certainly suggest themselves to a person skilled in the art. Accordingly, the embodiments presented herein are not meant to limit the scope of this invention. 
     FIGS. 11 a ,  11   b ,  11   c  show how the Hi-Z wire may be applied to polarization and to phase control in reflection. The conventional wire grid polarizer is shown in FIG. 11 a . The electric field component aligned with the wire is reflected, and the component orthogonal to the wire passes through the grid unaffected. The same is true for the Hi-Z grid shown in FIG. 11 b , when the frequency is below the resonance transition. However, at a higher frequency, the sign of the reflection coefficient reverses and the radiation is transmitted. Thus depending on the frequency, the radiation will pass through the grid unaffected or will be polarized by the grid. Such a polarizer, formed by a Hi-Z wire grid, is therefore frequency selective. 
     An alternative grid configuration is shown in FIG. 11 c , where conventional wires  30  are interspersed with Hi-Z wires  31  to form a Low/Hi-Z wire grid reflector. If this one-dimensional grid is such that the wires are spaced one-half wavelength apart, with alternating wires having low and high impedance, the frequency of the incident radiation  32  being equal to the resonant frequency of the Hi-Z wires  31 , then the grid will reflect radiation efficiently into two directions along the plane of the grid, the plane of the grid being orthogonal to the incident beam  32 , as illustrated by FIG. 11 d . This can be understood by recalling that the radiation in a particular direction can be calculated by adding up the radiation provided by the vector currents along all radiating surfaces. In the direction perpendicular to the plane of the grid, the currents on each alternating wire interfere destructively. In the direction along the grid, the currents on each wire interfere constructively. Since the Hi-Z wires  31  have an impedance which varies with frequency, the radiation angle can be tuned by either tuning the frequency of the incoming radiation  32 , or by tuning the resonance frequency of the Hi-Z wires  31 . FIG. 11 e  shows an example in which the Hi-Z wires have been tuned so as to set the reflection angle to a desired value. The radiation from each alternating wire will interfere constructively in a direction that depends on the impedance of the Hi-Z wires  31  and the frequency of the incoming wave  32 . Thus, by tuning the frequency of the incoming wave  32 , or by tuning the Hi-Z wires  31 , one can steer the reflected beams  34 ,  35 . 
     However, the surface will also radiate into the backward direction, since it is not entirely reflective. This problem may be solved by using a ground plane  36 , as shown in FIG. 11 f . The ground plane is preferably positioned about one-quarter wavelength below the grid of wires. One remaining problem is the formation of a second beam  34  into the opposite direction, away from the main beam  35 . This may be solved by varying the spacing between the wires. FIG. 11 g  shows a grid in which the low impedance wires  30  and the Hi-Z wires  31  are grouped in pairs, each pair containing a low impedance wire  30  and a Hi-Z wire  31 . In this example, the spacing between two adjacent pairs is greater than the spacing between two wires forming a pair. The spacing can be adjusted so that, for a particular impedance condition on the Hi-Z wires  31 , the currents interfere constructively with the currents on the ordinary wires  30  in a particular direction to form a main beam  38 , but interfere destructively in the opposite direction to form a weaker secondary beam  37 . This is analogous to a blaze angle on an optical grating. 
     In a preferred embodiment of the Low/Hi-Z grid reflector, the wires are preferably attached to a rectangular or square frame made of a non-conductive material, the wires being disposed parallel to two sides of the frame. 
     As noted above, by appropriately tuning the resonance frequency of the individual wires forming the grid, a reflection phase gradient can be created across the array. This allows for one-dimensional steering of a beam in a direction contained in a plane which is perpendicular to both the plane containing the wires and the wires themselves. Additionally, if the resonance frequency of each wire is varied along the length of the wire, beam-steering can be realized in a direction contained in a plane which is perpendicular to the plane containing the wires and parallel to the wires. In this manner, two-dimensional beam-steering is achieved. 
     FIG. 13 c  shows a computer simulation of an embodiment of the Hi-Z wire shown in FIGS. 13 a  and  13   b . By way of this example, the concepts associated with the present invention are demonstrated. The structure modeled is a straight wire  70  loaded with external cavities  71 . The cavities  71  consist of an outer metallic sheath around the wire. Periodic breaks are present in the sheath which define the locations of the individual cavities  71 . Between the breaks the sheath is shorted to the inner wire through the connections  72 . One period  73  of this structure was modeled using HFSS, a commercially available finite element modeling package available from Agilent. For the purpose of simulation, the structure is placed in a so-called “TEM waveguide” consisting of electric walls on two sides and magnetic walls on the other two sides. This geometry simulates a infinite array of such structures being irradiated by plane waves at normal incidence. 
     The inner wire  70  is 0.2 cm in diameter, the outer part of the sheath is 0.1 cm thick and 0.6 cm in diameter. The narrow gap forming the capacitive part of the cavity is 0.1 cm wide. The structure is illustrated in FIGS. 13 a  and  13   b . FIG. 13 c  shows the magnitude of the electric field at 10 GHz. The structure has a resonance frequency of about 8 GHz, which can be seen in the transmission  60  and reflection  61  plots of FIG. 14 a . At the resonance frequency, the reflection drops and the transmission reaches 100%. 
     At the resonance frequency of 8 GHz, the free-space wavelength is 3.75 cm. The diameter of the wire is only 0.6 cm, which is less than the one-half wavelength thickness that would normally be expected. This is due to capacitive loading of the cavity, and is analogous to what is routinely achieved with Hi-Z surfaces. The diameter could be lowered further by overlapping the metal plates, using one of the methods described above. 
     The phase of the transmitted  63  and reflected  62  signals are shown in FIG. 14 b . The sudden jumps in the reflection phase are due to the ambiguity of inverse trigonometric functions, and are an artifact of the simulation method. The important feature to note is that the transmission phase crosses through zero near the resonance frequency, as expected. The slight shift toward higher frequencies is related to the non-zero radius of the wire. 
     This simulation confirms that structures of the type presented here can appear transparent to electromagnetic waves near their designed resonance frequency, even though they have a core of solid metal. 
     Having described the invention in connection with certain embodiments thereof, modifications will certainly suggest themselves to those skilled in the art. As such, the invention is not to be limited to the disclosed embodiments except as required by the appended claims.