Patent Publication Number: US-7215296-B2

Title: Switched multi-beam antenna

Description:
RELATED APPLICATIONS 
     This application claims the benefit of U.S. Provisional Application No. 60/562,097 filed Apr. 12, 2004, entitled MONOPOLE YAGI ANTENNA ARRAYS UTILIZING A COMMON REFLECTOR and is a Continuation-in-Part of U.S. application Ser. No. 10/510,157, filed Sep. 27, 2004, titled: AN ANTENNA SYSTEM WITH A CONTROLLED DIRECTIONAL PATTERN, A TRANSCEIVER AND A NETWORK PORTABLE COMPUTER (which claimed the benefit of PCT/RU03/00119 filed Mar. 24, 2003 and Russian application 2002108661 filed Mar. 27, 2002). Each of the foregoing applications are hereby incorporated by reference. 
    
    
     FIELD OF THE INVENTION 
     This invention relates to wireless communication systems including direction-agile antennas useful in such systems. 
     BACKGROUND OF THE INVENTION 
     In wireless communication systems, antennas are used to transmit and receive radio frequency signals. In general, the antennas can be omni-directional or unidirectional. In addition, there exist antenna systems which provide directive gain with electronic scanning rather than being fixed. However, many such electronic scanning technologies are plagued with excessive loss and high cost. In addition, many of today&#39;s wireless communication systems provide very little room for antennae elements. 
     Traditional Yagi-Uda arrays consist of a driven element (by this we mean a signal is fed to the element by a transmitter or other signal source), called the driver or antenna element, a reflector, and one or more directors. The reflector and directors are not driven, and are therefore parasitic elements. By choosing the proper length and spacing of the reflector from the driven element, as well as the length and spacing of the directors, the induced currents on the reflector and directors will re-radiate a signal that will additively combine with the radiation from the driven element to form a more directive radiated beam compared to the driven element alone. The most common Yagi-Uda arrays are fabricated using a dipole for the driven element, and straight wires for the reflector and directors. The reflector is placed behind the driven element and the directors are placed in front of the driven element. The result is a linear array of wires that together radiate a beam of RF energy in the forward direction. The directivity (and therefore gain) of the radiated beam can be increased by adding additional directors, at the expense of overall antenna size. The director can be eliminated, which leads to a smaller antenna with wider beam width coverage compared to Yagi antennas utilizing directors. The dipole element is nominally one-half wavelength in length, with the reflector approximately five percent longer than the dipole and the director or directors approximately five percent shorter than the dipole. The spacing between the elements is critical to the design of the Yagi and varies from one design to another; element spacing will vary between one-eighth and one-quarter wavelength. 
     SUMMARY OF THE INVENTION 
     One aspect of the invention includes an antenna system including a reflective layer having an upper surface and a lower surface; a plurality of antenna elements proximate the upper surface of the reflective layer; one or more reflectors electrically coupled to the reflective layer and positioned to operate as a reflector for each of the plurality of antenna elements; and a switch coupled to each of the plurality of antenna elements and configured to select an active state or inactive state for each of the plurality of antenna elements. The switch can be configure to select an active state for more than one antenna element at one time. The reflective layer can comprise a primary reflective surface to which the plurality of antenna elements are located proximate and a secondary reflective surface. A plurality of electrically conductive standoffs can couple the primary reflective surface to the secondary reflective surface. The system can further include a radio coupled to the switch. The radio can be located proximate the lower side of the reflective surface opposite the antenna elements. 
     Each of the plurality of antenna elements can include a center section coupled to the switch at a first end of the center section proximate the reflective layer; a top section extending from a second end of the center section opposite the first end of the center section; an inductive section extending from the reflective layer to the top section; and a capacitive section extending from the top section towards the reflective layer. 
     The system can include one or more directors. The directors can be located on the lower surface of the reflective surface. The one or more directors can also be located on the upper surface of the reflective surface. 
     In another aspect, a communication device includes a base layer; a reflective layer formed on the base layer and having an upper surface and a lower surface; a plurality of antenna elements proximate the upper surface of the reflective layer; one or more reflectors electrically coupled to the reflective layer and positioned to operate as a reflector for each of the plurality of antenna elements; a radio configured to transmit a radio frequency signal; a switch coupled the radio and to each of the plurality of antenna elements and configured to select an active state or inactive state for each of the plurality of antenna elements in response to a control signal; and a controller coupled to the switch and configured generate a control signal to control the switch. 
     A further aspect of the invention is a method of manufacturing an antenna assembly including providing a base layer having an upper surface and a lower surface; forming a primary reflective surface on the base layer; providing a plurality of antenna elements proximate the upper surface of the base layer; providing one or more reflectors proximate the upper surface of the base layer positioned to operate as a reflector for each of the plurality of antenna elements and electrically coupling the one or more reflectors to the primary reflective surface; and coupling a switch, configured to select an active state or inactive state for each of the plurality of antenna elements in response to a control signal, to each of the plurality of antenna elements. The method can further include matching the impedance of each of the plurality of antenna elements to the switch to minimize losses. Alternatively, The method can include adjusting the impedance of each of the plurality of antenna elements with respect to the switch such that the mismatch loss is equal for the cases when one of the plurality of antenna elements in the active state and when two of the plurality of antenna elements are in the active state. The impedance of an antenna element can be adjusted by shorting one or more impedance tuning pads to the antenna element. In addition, one or more impedance tuning pads can be shorted to each other. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       These and other aspects, advantages and details of the present invention, both as to its structure and operation, may be gleaned in part by a study of the accompanying drawings, in which like reference numerals refer to like parts. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. 
         FIG. 1A  is a perspective view of a four element antenna assembly. 
         FIG. 1B  is a plan view of the antenna assembly shown in  FIG. 1A . 
         FIG. 1C  is a side view of an antenna assembly with dipole antenna elements. 
         FIG. 2  is a plan view of the underside of the antenna assembly. 
         FIG. 3  is a detailed cross-section of a portion of the assembly of  FIG. 1   a.    
         FIGS. 4A–E  are side views of alternative configurations of monopole elements. 
         FIG. 5  is a schematic block diagram representation of a wireless communication device. 
         FIG. 6  is a perspective view of an antenna element coupled to secondary reflective surface. 
         FIG. 7  is a perspective view of a four element antenna assembly with directors. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Certain embodiments as disclosed herein provide for systems and methods for a wireless communication device or system having a switched multi-beam antenna and methods for manufacturing the same. For example, one system and method described herein provides for a plurality of monopole antenna elements mounted on a reflective surface. A common reflector cooperates with each active antenna element to create a directed transmission or a direction of positive gain. A switch allows for activating one or more of the antenna elements to vary the direction of the transmission. All of the antenna elements can be activated to cause the antenna assembly to transmit omni-directionally. Directors above or below the reflective surface can be used to modify the characteristics of the antenna. The system can be used with various wireless communication protocols and at various frequency ranges. For example, the system can be used at frequency ranges including 2.4, Giga hertz, 2.8 Giga hertz, and 5.8 Giga hertz. 
     After reading this description it will become apparent to one skilled in the art how to implement the invention in various alternative embodiments and alternative applications. However, although various embodiments of the present invention will be described herein, it is understood that these embodiments are presented by way of example only, and not limitation. As such, this detailed description of various alternative embodiments should not be construed to limit the scope or breadth of the present invention as set forth in the appended claims. 
       FIG. 1A  is a perspective view of a four element antenna assembly  10 .  FIG. 1B  is a plan view of the antenna assembly  10 . The assembly includes a reflective layer or surface  12  which is reflective to the radio waves with which the antenna assembly will be used. In the embodiment depicted in  FIGS. 1A–B , the reflective surface is a ground plane which is formed on the upper surface of a base  14 . In this embodiment, the reflective surface  12  covers the entire upper surface of the base  14 . The reflective surface  12  can be a layer of copper or other conductive material formed on the base  14 . The reflective layer  12  does not necessarily have to be planar. In addition, the reflective surface can have discontinuities. For example, the reflective surface can be a mesh or can have openings. In one embodiment, the size of the discontinuities are one tenth or less of the wavelength to be transmitted. Unless otherwise indicated, references herein to wavelength refer to the wavelength of the radio waves with which the antenna assembly will be used. In one embodiment, the wavelength is between 1 and 12 inches, for example, 10 centimeters. 
     The base  14  can be a single or multi-layer printed circuit board. In one embodiment, four antenna elements identified as  16   a ,  16   b ,  16   c  and  16   d  are mounted on the base and extend above the reflective surface  12 . Alternatively, fewer or more antenna elements can be used. For example, three, five or six antenna elements can be used. Though the antenna elements are shown evenly distributed around the reflective layer, they can be arranged in other patterns. The antenna elements can be, for example, traditional monopoles or folded monopoles. The antenna elements can be formed of copper or other conductive materials. 
     A reflector element  18  is located centrally with regard to the four monopole elements  16   a–d . However, the exact location of the reflector  18  can vary. The reflector is mounted to the base  14  and is electrically coupled with the reflective surface  12 . In one embodiment, each leg of the reflector is shorted to the reflective surface. The reflector  18  is configured to act as a reflector for each of the monopole elements. Alternatively, more than one reflector can be provided. The reflector elements can be formed of copper or other conductive materials. The reflector  18  can be formed in various shapes. For example, the reflector can be circular or square in cross section. A reflector with a triangular cross section can be used when only three antenna elements are used. A reflector which provides a symmetrical surface to each antenna element is preferred. The reflector is preferably electrically longer in the direction of the polarization of the wave being transmitted than the antenna element with which it works. In order to minimize the physical height of the reflector, it includes four over hangs or arms with cause it to operate as an electrically longer element than its height. The electrical length of the reflector can also be adjusted through the use of lumped impedance between the reflector and the reflective surface. 
     The assembly depicted in  FIGS. 1   a–b  uses a single monopole element to cover a quadrant. The four monopole elements  16   a–d  utilize the common reflector  18 . This configuration allows the antenna to provides full coverage in the azimuth plane. The length of wire or material required to form a monopole and reflector (and optionally directors, not shown in this embodiment), is only one-half the length required to form a dipole and reflectors that are not in the vicinity of a reflective surface. When the reflective surface is made sufficiently large, the radiated energy is constrained to the hemisphere above the reflective surface on the side of the reflective surface to which the wire elements (monopoles and reflector) are attached. This allows for placing electronic components or other materials below the reflective surface (the side opposite of the antenna elements) without materially affecting the performance of the antenna assembly. As with traditional Yagi antennae design, the spacing between the elements typically varies between ⅛ and ¼ wavelength. In the embodiment shown in  FIGS. 1   a–b , directors are eliminated in order to provide a smaller antennae structure. 
     A switch is located on the lower surface of the base  14 , opposite the reflective surface  12 . The switch  60  is coupled to each of the monopole elements  16   a–d . The switch can be controlled to select either an active or inactive state for each of the antenna elements  16   a–d . For example, the switch can selectively apply a driving signal to any one or more of the monopole elements. Driving one of the monopole-type elements with a radio frequency (RF) signal causes that monopole element to radiate the RF signal. Currents are induced on the reflector which re-radiates the RF signal. The length and spacing of the antenna element and the reflector are chosen such that the RF signals radiated from each element in the antennae add constructively in the intended direction of radiation. 
       FIG. 1C  depicts an embodiment in which each of the antenna elements has a complementary antenna element which allows the pair of elements to operate as a dipole. Alternatively, different types of antenna elements can be used, for example, patch or coil elements. The antenna assembly in  FIG. 1C  is the same as that in  FIG. 1A  except that each antenna element  16   a–d  includes a complimentary element  16   e–h  located on the opposite side of the base  10  and electrically coupled to the antenna element on the other side of the base  14 . Further, there is a complementary reflector  19  located opposite the reflector  18 . All of the elements on the bottom or opposite side of the base operate and function in the same manner as their counter parts on the other side. The switch can be located on either side and controls the antenna elements in dipole pairs. Alternatively, the switch can control each antenna element separately. Further, the reflective surface is not needed for this embodiment. This allows for a more compact design in terms of the dimensions of the base. 
       FIG. 2  is a plan view of the underside of the antenna assembly  10 . In the embodiment depicted in  FIG. 2 , the switch  60  includes four pin diodes  20   a–d  and a control circuit  26 . Each of the pin diodes is located in series on the trace  24   a–d  which leads to the connection  23   a–d  to the respective antenna element  16   a–d  (see  FIG. 1A ). A control line  22   a–d  runs from the end of the trace proximate the antenna element to the control circuit  26 . An RF signal is supplied via connector  29  to the center point  30  which is coupled to each of the pin diodes. 
     The control circuit  26  receives a control signal via a connector  28 . In one embodiment the control signal is a four line or four input control signal. In one embodiment, the control circuit converts a positive 3 volt direct current input signal to a 12 volt direct current signal which is applied to the control line. The 12 volt signal causes the associated pin diode to act as a short to the RF signal. A six volt virtual ground signal is supplied to the center point by the virtual ground circuit  31 . The six volt virtual ground signal causes the pin diodes to provide a very good open condition when the 12 volt signal is not present and a ground signal is provided to the control line  22  by the control circuit  26 . 
     In operation, each of the four input lines corresponds to one of the antenna elements  16   a–d . When a 3 volt signal is present on a input line, the control circuit  26  supplies the 12 volt signal to the control line corresponding to that antenna element. When a zero volt signal is present on a input line, the control circuit provides a zero volt signal on the corresponding control line and the pin diode presents on open circuit to the antenna element. 
     Each of the traces coupling the antenna element to the pin diode has associated impedance tuning pads, for example tuning pad  25   a . To create the desired impedance, one or more of the tuning pads can be shorted (electrically connected) to the trace. In addition, tuning pads can be shorted to each other in order to provide additional impedance tuning options. 
     The four antenna array described here can generate multiple beams for optimizing the antenna gain in various directions. Each monopole element can be individually fed by the switch to form single beams. These four beams will provide quadrant coverage around the antenna array. Adjacent pairs of monopole elements can be fed simultaneously to form corner arrays, which provide increased gain at the angular region between the individual beams of the two antennas. Opposing pairs of elements can be combined to provide coverage in the two opposing directions. All four elements can be fed simultaneously to provide omni-directional coverage. The same variations can also be used with antenna assemblies have more or fewer antenna elements, for example, antenna assemblies having two, three, five or six or more antenna elements. 
     Using a switch to activate individual antenna elements as well as combined elements presents a challenge when impedance matching the antenna/switch assembly. A common port which tees out to four ports, with pin diodes or other active components providing a connection or producing an open circuit in each branch is the circuit topology used in one embodiment. If the antenna element is impedance matched to the switch or switch assembly to provide the lowest mismatch loss when a single antenna element is activated, the mismatch loss for the case where a corner array is formed will increase when compared to the single antenna case. This is due to the impedance of the two ports combining in parallel to present the resultant impedance at the common port of the switch that is one-half the value of the impedance of the single port case. The same rationale applies to the reverse scenario, where the antenna elements have optimized impedance values to produce a minimum mismatch loss for the case when a corner array is formed. Overall antenna performance can be improved by matching the antenna impedance such that the mismatch loss is equal (meaning approximately equal) for the two cases described above, activating a single antenna element and combining two elements to form an array. By matching the antenna assembly in this fashion, the radiation efficiency is equalized across all of the beams, and the return loss of the antenna assembly will remain constant as different antenna beams are formed. 
       FIG. 3  is a detailed view of the assembly  10  of  FIGS. 1A–B  showing one of the monopole elements  16  and a portion of the base  14  and reflective surface  12  in cross section. In this embodiment, the antenna element is a monopole element with a shape which resembles the letter “M” when viewed from the side. A center section  32  of the element  16  runs perpendicular to the reflective surface. Alternatively, different angles between the reflective surface and the center section  32  can be used, for example, eighty degrees or forty-five degrees. The center section  32  is coupled to the switch matrix at the end that approaches the reflective surface and is not coupled to the reflective surface. A top section  34  of the antenna element  16  is located at the end of the center section  32  opposite the reflective surface. The top section  34  branches to both sides of the center section  32 . The top section  34  may run parallel or substantially parallel to the reflective surface. An inductive section  36  extends from the reflective surface to the top section  34 . The inductive section can be parallel to the center section  32 . The inductive section  36  is short circuited to the reflective surface  12 . A capacitive section  38  extends towards the reflective surface  12  from the end of the top section  34  opposite to the inductive section  36 . The capacitive section  38  can be parallel to the center section  32 . The capacitive section  38  ends prior to making contact with the reflective surface. The inductive section  36  and the capacitive section  38  act as inductive and capacitive components, respectively, that can be adjusted to impedance match the antenna element  16  as needed by the requirements of the system in which it will be used. The inductive element  36  forms an inductive loop when combined with its image generated by the reflective surface. The capacitive section  38  forms a capacitive section at the reflective surface. 
     The configuration of the antenna element  16  described above can allow for the overall size (principally the height) of the antenna element  16  to be made smaller without a significant reduction in performance due to the reactive loading generated by these inductive and capacitive sections. The reduction in height can be quite important when the assembly  10  (see  FIG. 1A ) is placed within an enclosure, for example, a plastic enclosure. For example, the arrangement described above can minimize the contact between the antenna elements  12   a–d  and the plastic enclosure commonly used in wireless local area network (WLAN) communication devices. Preferably, the antenna elements do not touch the plastic enclosure. Most of the antenna element  16  is perpendicular to the reflective surface  12 . The reflective surface is typically parallel to the adjacent wall of the enclosure. Therefore, very little of the antenna element  12  is available to come into contact with the wall of the enclosure. 
     This is an advantageous feature since the close proximity of the plastic enclosure to the antenna element reduces the frequency of operation of the antenna element. This de-tuning of the antenna element is a common occurrence in embedded antenna applications. The antenna element must be dimensioned and tuned to resonate at a higher frequency than the intended frequency prior to insertion of the antenna assembly into the plastic enclosure, with a prior knowledge of the dielectric constant of the plastic material, its thickness, and distance from the antenna elements needed to insure a successful impedance match of the antenna assembly after embedding in the plastic enclosure. This “M” shaped antenna element  12  does not de-tune when placed inside the plastic enclosure, making this a robust design for applying to a wide variety of WLAN devices. 
       FIGS. 4A–E  are side views of alternative configurations of monopole elements that can be used to accommodate a wide variety of applications. Each of the monopole elements in  FIGS. 4A–E  are shown mounted to the base  14  above the reflective surface  12 .  FIG. 4A  depicts a straight monopole element  42 .  FIG. 4B  depicts a folded monopole  44 .  FIG. 4C  depicts a bent monopole  46 .  FIG. 4D  depicts a folded bent monopole  48 .  FIG. 4E  depicts a top loaded monopole  50 . These monopoles can be used in place of the “M” shaped monopole elements  16   a–d  shown in  FIG. 1A . In particular, in situations where sufficient height is available, the monopole element can be a traditional monopole or a folded monopole. The choice between the two provides an option for higher antenna impedance (folded monopole) for switch topologies that require a high terminating impedance. A resonant monopole is on the order of 0.20 to 0.25 wavelengths in length. When the application requires a reduced height approach, the monopole element can take other forms: a bent monopole, a bent folded monopole, or a top loaded monopole for example. 
       FIG. 5  is a schematic block diagram representation of a wireless communication device utilizing the antenna assembly  10 . For example, the wireless communication device can be a wireless router, a cellular telephone, a wireless communication card for a portable computer or any other type of wireless communication device. The device includes a housing which is not shown. The switch  60  can be a pin diode type switch as described above. Other suitable switches can be used, for example, transistor switches and micro-electro-mechanical switches. The switch  60  is configured to couple the output  62  of the switch to one or more of the antenna elements  16   a–d . The output  62  can be coupled to a radio receiver/transmitter subassembly  66 . The switch  60  receives control signals at its control input  64 . The control signal may be sent from a radio processor subassembly  68 . The signals received at the control signal input  64  of the switch  60  control the operation of the switch. For example, the control signals can cause the switch to couple its output port  62  to one or more of the antenna elements  16   a–d . The wireless communication device also typically includes a central processing unit  70 . It is also possible to configure the system such that the control signals to the control signal input port  64  of the switch  60  are sent from the central processing unit  70 . The central processing unit  70  and the radio processor subassembly  68  are collectively referred to as the controller  69 . In general, it is the controller  69  which controls the switch  60 . The non-antenna elements of the wireless communication device are enclosed within box  67 . It should be understood that in general the non-antenna elements  67  are coupled to the output  62  of the switch  60  and to the control signal port  64  of the switch but that the non-antenna elements  67  can be configured in various manners and arrangements without departing from the scope of the present invention. 
     When using mono-pole type antenna elements, a reflective surface is typically required for operation. To provide efficient radiation into the hemisphere above the plain in which the reflective surface is positioned, the dimensions of the reflective surface are typically on the order of one wavelength or greater per side (if the reflective surface is rectangular in shape). A reflective surface with smaller dimensions impairs the ability of the image of the antenna element formed by the reflective surface to properly form. In addition, excess radiation in the hemisphere below the reflective surface can occur in such situations which reduces the directivity of the antenna element in the direction of the upper hemisphere. While it can be advantageous to have a reflective surface with dimensions on the order of at least one wavelength. Alternatively, directors can be added to the side of the reflective surface  10  opposite the antenna elements  16   a–d  in the embodiment shown in  FIG. 1A  to assist in modifying the antenna beam characteristics. 
     As was noted earlier, the reflective surface does not need to be formed of a single conductive element located in a single plane. For example, referring to  FIG. 6 , the antenna element  10  of  FIG. 1A  having a reflective surface  12  is shown coupled to a larger secondary reflective surface  70 . In operation, the reflective surface  12  and the secondary reflective surface  70  act as a single reflective surface. In the embodiment depicted in  FIG. 7 , reflective surface  12  of the antenna element  10  may have the length of its sides being less than one wavelength of the RF for which the assembly is optimized. The secondary reflective surface  70  can be the ground layer of a printed circuit board  74  or some other metal surface. The reflective surface  12  of the antenna assembly  10  is electrically coupled (shorted) to the secondary reflective surface by a series of electrically conducting stand-offs  72 . Alternatively, the coupling can be capacitive or inductive. The stand-offs  72  can be biased against contacts on the printed circuit board  74 , for example by a mechanical coupling mechanism such as a clamp or a threaded fastener. This eliminates the need to solder the standoffs to the printed circuit board  74 . Therefore, the space on the printed circuit board under the assembly  10  can be used for components that need to be tested after soldering. The assembly  10  can be mechanically attached after that. 
     The number of stand-offs used can be varied. Maintaining a spacing between the stand-offs  72  of approximately ⅕ of a wavelength or less can improve the performance of the system. Coupling the reflective surface  10  to the secondary reflective surface  70  can be thought of as forming a composite reflective surface with which the antenna elements  16   a–d  and the reflector  18  cooperate for transmission. The embodiment depicted in  FIG. 6  allows for the antenna element to have a reduced size without losing the benefits of a larger reflective surface. This can be particularly advantageous when the secondary reflective surface  70  is the ground layer or ground plane of a circuit board  74  used in a wireless communication device such as the device depicted in  FIG. 5 . 
     When the secondary reflective surface is formed on the printed circuit board of a communication device, the elements of the communication device can adversely effect the operation of the antenna assembly  10 . The electrical leads to certain elements such as the central processing unit  70  (see  FIG. 5 ) can resonate with the transmissions of the antenna assembly and drain off transmitted signal strength. Therefore, those leads are placed under the ground plane layer  70  of the printed circuit board  74 . Similarly, placing as much ground plane as possible on the top surface of the circuit board  74  will provide better performance and better shielding of elements below that surface. Similarly, elements which resonate can also be shielded, for example, by using a shielded cover. For example, covering all unused surface area with ground plane is beneficial. 
     In addition capacitors with very little capacitance, for example 15–20 pico-farads, can be placed in series with wires or traces that resonate. That minimizes the resonating and does not interfere with the operation of the other devices in the system which operate at a lower frequency than the RF frequency transmitted by the antenna assembly. For example, the wires contained within an RJ-45 connector may resonate and that resonation can be minimized by placing the proper capacitance in series with those wires. Additionally, large elements on the circuit board  74 , for example, capacitors  78 , are positioned as far as possible from the antenna elements  16   a–d  and the reflective surface  12  to minimize interference with the RF transmission 
     The radio  66  is shown in this embodiment as a PCI card mounted on the circuit board  74  and coupled to the antenna assembly by a coaxial cable  75 . Alternatively, the radio can be assembled on the bottom side of the base  14  of the antenna assembly  10 . Additionally, in one embodiment, the radio is mounted directly on the board  74 . 
       FIG. 7  is a perspective view of an alternative embodiment of the antenna assembly. In the assembly shown in  FIG. 7 , each antenna element  82   a–d  has an associated director  84   a–d . The common reflector  86  is configured as a simple cross piece. A reflective surface  88  is a ground plane. In the embodiment depicted in  FIG. 7 , the monopole antenna elements are approximately ¼ wavelength in length. The reflector  86  is approximately five percent longer than the antenna element and the directors are approximately five percent shorter in length than the antenna elements. This antenna assembly can be used in the wireless communication device depicted in  FIG. 5  and can utilize the switch described in  FIGS. 2 and 5 . 
     The above description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the principles defined herein can be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.