Adaptive antenna for use in wireless communication systems

Information

  • Patent Grant
  • 6515635
  • Patent Number
    6,515,635
  • Date Filed
    Tuesday, May 1, 2001
    23 years ago
  • Date Issued
    Tuesday, February 4, 2003
    21 years ago
Abstract
A directive antenna includes plural antenna elements in an antenna assemblage. A feed network connected to the antenna elements includes at least one switch to select a state of one of the antenna elements to be in an active state in response to a control signal. The other antenna elements are in a passive state, electrically coupled to an impedance to be in a reflective mode. The antenna elements in the passive state are electromagnetically coupled to the active antenna element, allowing the antenna assemblage to directionally transmit and receive signals. The directive antenna may further include an assisting switch associated with each antenna element to assist coupling the antenna elements, while in the passive state, to the respective impedances. The antenna assemblage may be circular for a 360° discrete scan in N directions, where N is the number of antenna elements. The directive antenna is suitable for use in a high data rate network having greater than 50 kbits per second data transfer rates, where the high data rate network may use CDMA2000, 1eV-DO, 1Extreme, or other such protocol.
Description




FIELD OF INVENTION




This invention relates to cellular communication systems, and, more particularly, to an apparatus for use by mobile subscriber units to provide directional transmitting and receiving capabilities.




BACKGROUND OF THE INVENTION




The bulk of existing cellular antenna technology belongs to a low- to medium-gain omni-directional class. An example of a unidirectional antenna is the Yagi antenna shown in FIG.


1


. The Yagi antenna


100


includes reflective antenna elements


105


, active antenna element


110


, and transmissive antenna elements


115


. During operation, both the reflective and transmissive antenna elements


105


,


115


, respectively, are electromagnetically coupled to the active antenna element


110


. Both the reflective antenna elements


105


and the transmissive antenna elements


115


re-radiate the electromagnetic energy radiating from the active antenna element


110


.




Because the reflective antenna elements


105


are longer than the active antenna element


110


and spaced appropriately from the active antenna element


110


, the reflective antenna elements


105


serve as an electromagnetic reflector, causing the radiation from the active antenna element


110


to be directed in the antenna beam direction


120


, as indicated. Because the transmissive antenna elements


115


are shorter than the active antenna element


110


and spaced appropriately from the active antenna element


110


, electromagnetic radiation is allowed to propagate (i.e., transmit) past them. Due to its size, the Yagi antenna


100


is typically found on large structures and is unsuitable for mobile systems.




For use with mobile systems, more advanced antenna technology types provide directive gain with electronic scanning, rather than being fixed, as in the case of the Yagi antenna


100


. However, the existing electronics scan technologies are plagued with excessive loss and high cost, contrary to what the mobile cellular technology requires.




Conventional phased arrays with RF combining networks have fast scanning directive beams. However, the feed network loss and mutual coupling loss in a conventional phased array tend to cancel out any benefits hoped to be achieved unless very costly alternatives, such as digital beam forming techniques, are used.




In U.S. Pat. No. 5,905,473, an adjustable array antenna—having a central, fixed, active, antenna element and multiple, passive, antenna elements, which are reflective (i.e., re-radiates RF energy)—is taught. Active control of the passive elements is provided through the use of switches and various, selectable, impedance elements. A portion of the re-radiated energy from the passive elements is picked up by the active antenna, and the phase with which the re-radiated energy is received by the active antenna is controllable.




SUMMARY OF THE INVENTION




The present invention provides an inexpensive, electronically scanned, antenna array apparatus with low loss, low cost, medium directivity, and low back-lobe, as required by high transmission speed cellular systems operating in a dense multi-path environment. The enabling technology for the invention is an electronic reflector array that works well in a densely packed array environment. The invention is suitable for any communication system that requires indoor and outdoor communication capabilities. Typically, the antenna array apparatus is used with a subscriber unit. Other than the feed network, the antenna apparatus can be any form of phased array antenna.




According to the principles of the present invention, the directive antenna includes multiple antenna elements in an antenna assemblage. A feed network connected to the antenna elements includes at least one switch to select a state of one of the antenna elements to be in an active state in response to a control signal. The other antenna elements are in a passive state, electrically coupled to an impedance to be in a reflective state. The antenna elements in the passive state are electromagnetically coupled to the selected active antenna element, allowing the antenna assemblage to directionally transmit and receive signals. In contrast to U.S. Pat. No. 5,905,473, which has at least one central, fixed, active, antenna element, the present invention selects one passive antenna element to be in an active state, receiving re-radiated energy from the antenna elements remaining in the passive state.




The directive antenna may further include an assisting switch associated with each antenna element to assist coupling the antenna elements, while in the passive state, to the respective impedances. The impedances are composed of impedance components. The impedance components include a delay line, lumped impedance, or combination thereof. The lumped impedance includes inductive or capacitive elements.




In the case of a single switch in the feed network, the switch is preferably a solid state switch or a micro-electro machined switch (MEMS).




The antenna assemblage may be circular for a 360° discrete scan in N directions, where N is the number of antenna elements. At least one antenna element may be a sub-assemblage of antenna elements. The antenna elements may also be telescoping antenna elements and/or have adjustable radial widths. The passive antenna elements may also be adjustable in distance from the active antenna elements.




The impedance to which the antenna elements are coupled in the passive state are typically selectable from among plural impedances. A selectable impedance is composed of impedance components, switchably coupled to the associated antenna element, where the impedance component includes a delay line, lumped impedance, or combination thereof. The lumped impedance may be a varactor for analog selection, or capacitor or inductor for predetermined values of impedance.




The directive antenna is suitable for use in a high data rate network having greater than 50 kbits per second data transfer rates. The high data rate network may use CDMA2000, 1eV-DO, 1Extreme, or other such protocol.











BRIEF DESCRIPTION OF THE DRAWINGS




The foregoing and other objects, features and advantages of the invention will be apparent from the following more particular description of preferred embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention.





FIG. 1

is a prior art directional antenna;





FIG. 2

is an illustration of an environment in which the present invention directive antenna may be employed;





FIG. 3

is a mechanical diagram of the directive antenna of

FIG. 2

operated by a feed network;





FIG. 4

is a schematic diagram of an embodiment of the feed network having a switch used to control the directive antenna of

FIG. 3

;





FIG. 5

is a schematic diagram of a solid state switch having losses exceeding an acceptable level for use in the circuit of

FIG. 4

;





FIG. 6

is a schematic diagram of an alternative embodiment of the feed network used to control the directive antenna of

FIG. 3

;





FIG. 7

is a schematic diagram of an alternative embodiment of the feed network of

FIG. 6

;





FIG. 8

is a schematic diagram of yet another alternative embodiment of the feed network of

FIG. 6

;





FIG. 9

is a schematic diagram of an alternative embodiment of the feed network of

FIG. 4

;





FIG. 10

is a schematic diagram of an alternative embodiment of the directive antenna of

FIG. 3

having an omni-directional mode;





FIG. 11

is a schematic diagram of yet another alternative embodiment of the directive antenna of

FIG. 3

; and





FIG. 12

is a flow diagram of an embodiment of a process used to operate the directive antenna of FIG.


3


.











DETAILED DESCRIPTION OF THE INVENTION




A description of preferred embodiments of the invention follows.





FIG. 2

is an environment in which a directive antenna, also referred to as an adaptive antenna, is useful for a subscriber unit (i.e., mobile station). The environment


200


shows a passenger


205


on a train using a personal computer


210


to perform wireless data communication tasks. The personal computer


210


is connected to a directive antenna


215


. The directive antenna


215


produces a directive beam


220


for communicating with an antenna tower


225


having an associated base station (not shown).




As the train pulls away from train station


230


, the angle between the directive antenna


215


and the antenna tower


225


changes. As the angle changes, it is desirable that the directive antenna


215


change the angle of the directive beam


220


to stay on target with the antenna tower


225


. By staying directed toward the antenna tower


225


, the directive beam


220


maximizes its gain in the direction of the antenna tower


225


. By having a high gain between the antenna tower


225


and the directive antenna


215


, the data communications have a high signal-to-noise ratio (SNR).




Techniques for determining the direction of the beams in both forward and reverse links (i.e., receive and transmit beams, respectively, from the point of view of the subscriber unit) are provided in U.S. patent application Ser. No. 09/776,396 filed Feb. 2, 2001, entitled “Method and Apparatus for Performing Directional Re-Scan of an Adaptive Antenna,” by Proctor et al., the entire teachings of which are incorporated herein by reference. For example, the subscriber unit may optimize the forward link beam pattern based on a received pilot signal. The reverse link beam pattern may be based on a signal quality of a given received signal via a feedback metric over the forward link. Further, the subscriber unit may steer a reverse beam in the direction of a maximum received power of a forward beam from a given base station, while optimizing a forward beam on a best signal-to-noise (SNR) or carrier-to-interference (C/I) level.





FIG. 3

is a close-up view of an embodiment of the directive antenna


215


. The directive antenna


215


is an antenna assemblage having five antenna elements


305


. The antenna elements


305


are labeled A-E.




The antenna elements


305


are mechanically coupled to a base


310


, which includes a ground plane on the upper surface of the base. By arranging the antenna elements


305


in a circular pattern, the directive antenna


215


can scan discretely in


360


, at 72 intervals, as indicated by beams


315




a


,


315




b


, . . . ,


315




e


corresponding to antenna elements


305


(A-E). In other words, one antenna element


305


is active at any one time as provided by feed network


300


. Thus, if antenna A is active, then a respective antenna beam


315




a


is produced, since antenna elements B-E are in a reflective mode while antenna A is active. Similarly, the other antenna elements


305


produce beams, when active, in a direction away from the reflective antenna elements. It should be understood that the directive antenna is merely exemplary in antenna element count and configuration and that more or fewer antenna elements


305


and configuration changes may be employed without departing from the principles of the present invention.




The low loss of the directive antenna


215


is realized by using practically lossless reflective elements, and only one active element, which is selectable by a switch, as later described. Low cost is achieved by changing from the conventional RF combining network concept, which employs power dividers and costly phase shifters, to a passive reflector array. Medium directivity and low back lobe are made possible by keeping the element spacing to a small fraction of a wavelength. The close spacing normally means high loss, due to excess mutual coupling. But, in a reflective mode, the coupled power is re-radiated rather than lost.




Electronic scanning is implemented through a relatively low loss, single-pole, multi-throw switch, in one embodiment. Continuous scanning, if opted, is achieved through perturbing the phases of antenna elements in the reflective mode.




The directive antenna


215


typically has 7 to 8 dBi of gain, which is an improvement over the 4 to 5 dBi found in comparable conventionally fed phased arrays. Various embodiments of the directive antenna


215


and feed network


300


are described below.





FIG. 4

is a schematic diagram of the directive antenna


215


having an embodiment of a feed network comprising a single switch to control which antenna element


315


is active. The switch


400


is a single-pole, multiple-throw switch having the pole


402


connected to a transmitter/receiver (Tx/Rx) (not shown). The switch


400


has a switching element


410


that electrically connects the pole


402


to one of five terminals


405


. The terminals


405


are electrically connected to respective antenna elements


305


via transmission lines


415


. The transmission lines are 50-ohm and have the same length, L, spanning from the switch


400


to the antenna elements


305


.




In this embodiment, the switch


400


is shown as being a mechanical type of switch. Although possible to use a mechanical switch, a mechanical switch tends to be larger in physical dimensions than desirable, plus not typically robust for many operations and slow. Therefore, switches of other types of technologies are preferably employed. No matter the type of switch technology chosen, the performance should be high impedance in the ‘open’ state, and provide excellent transmittance (i.e., low impedance) in the ‘closed’ state. Once such technology is micro-electro machine switch (MEMS) technology, which does, in fact, provide “hard-opens” (i.e., high impedance) and “shorts” (i.e., very low impedance) in a mechanical manner.




Alternatively, gallium arsenide (GaAs) provides a solid-state switch technology that, when high-enough quality, can provide the necessary performance. The concern with solid-state technology, however, is consistency and low-loss reflectivity from port-to-port and chip-to-chip. Good quality characteristics allow for high quantity production rates yielding consistent antenna characteristics having improved directive gain. Another solid state technology embodiment includes the use of a pin diode having a 0.1 dB loss, as discussed below in reference to FIG.


6


.




In operation, a controller (not shown) provides control signals to control lines


420


that control the state of the switch


400


. The controller may be any processing unit, digital or analog, capable of performing typical processing and control functions. A binary coded decimal (BCD) representation of the control signal determines which antenna element


305


is active in the antenna array. The active antenna, again, determines the direction in which the directive beam is directed.




In the state shown, the switch


400


couples the Tx/Rx to antenna A. If the switch


400


were coupled to more than eight antenna elements, then more than three control lines


420


would be necessary (e.g., four control lines can select sixteen different switch states).





FIG. 5

is an example of a solid state switch


500


that has been found less optimal than a switch providing a hard open. The solid state switch


500


has a single-pole, double-throw configuration. In the closed-state as shown, the switch


500


has a pole


505


providing signals from the Tx/Rx to the antenna


305


. However, in the closed-state, there is electrical coupling from the pole


505


to a ground terminal


510


.




The electrical coupling is due to the fact the solid-state technology (e.g., CMOS) does not provide complete isolation from the pole


505


to the ground terminal


510


in the state shown. As a result, there is a −1.5 dB loss in the direction from the pole


505


to the ground terminal


510


, and a reflected loss of −1.5 dB from the ground terminal


510


back to the pole


505


. The cumulative loss is −3 dB. In other words, the advantage gained by using the directive antenna


215


is lost due to the electrical characteristics of this solid state switch


500


. In the other switch embodiments described herein, the losses described with respect to this solid state switch


500


are not found, and, therefore, offer viable switching solutions.





FIG. 6

is a schematic diagram of an alternative five element antenna array


215


. The antenna array


215


is fed by a single-path network


605


. The network


605


includes five 50-ohm transmission lines


610


, each being connected to a respective antenna element


305


. The other end of each transmission line


610


is connected respectively to a switching diode


615


. Each diode


615


is connected, in turn, to one of five additional 50 ohm transmission lines


620


. The transmission lines


620


are also connected to a 50-ohm transmission line


625


at a junction


630


. The transmission line


625


is connected to the junction


630


and an output


635


.




In use, four of the five diodes


615


are normally open. The open diodes serve as open-circuit terminations for the four associated antenna elements so that these antenna elements are in a reflective mode. The remaining diode is conducting, thus connecting the fifth antenna to the output


635


and making the respective antenna active. All the transmission lines


610


have the same impedance because there is no power combining; there is only power switching. Selection of the state of the diodes is made through the use of respective DC control lines (not shown).




Other embodiments of the invention differ slightly from the embodiment of FIG.


6


. For example, another embodiment, shown in

FIG. 7

, has the antenna array


215


having five antenna elements


305


, each being connected to one of five transmission lines


610


. Each of the transmission lines


610


, is connected, in turn, to a switching diode


615


and a quarter-wave line


705


connecting at a junction


630


. The quarter-wave lines


705


are connected to an output


635


through an output line


625


.




In operation, four of the five diodes


615


are shorted. Through a respective quarter-wave line


705


, each diode


615


appears as an open circuit when viewed from the junction


630


. This is the dual of the circuit discussed above in reference to

FIG. 6

, so that the impedance shown to the reflective antenna elements


305


is a short circuit. It is further observed that the lengths of the transmission lines


610


connecting the diodes


615


to the antenna elements


305


can be sized to adjust the amount of phase delay between the diodes


615


and antenna elements


305


.





FIG. 8

is yet another embodiment of a feed network for controlling the antenna array


215


. Shown is a single branch


800


of the feed network, where the single branch


800


provides continuous scanning rather than mere step scanning, as in the case of the branches of the previous network


605


. The continuous scanning is achieved by providing individual phase control to the reflective elements.




There are three diodes on each branch


800


. One diode is a first switching diode


615


, located closest to the junction


630


, which is used for the selection of the antenna element


305


that is to be active. The second diode is a varactor


805


, which provides the continuously variable phase to the antenna element


305


when in a reflective mode. The third diode is another switching diode


615


, which adds one digital phase bit to the antenna element


305


when in the reflective mode, where the phase bit is typically 180°. The phase is added by the delay loop


810


, which is coupled to both anode and cathode of the second switching diode


615


. The phase bit is used to supplement the range of the varactor


805


. The capacitors


815


are used to pass the RF signal and inhibit passage of the DC control signals used to enable and disable the diodes


615


.





FIG. 9

is yet another embodiment in which one of the antenna elements


305


is in active mode, and four of the five antenna elements


305


are in reflective modes. A central switch


400


directs a signal to one of the five antenna elements


305


in response to a control signal on the control lines


420


. As shown, the switch


400


is directing the signal to antenna A via the respective transmission line


415


.




In this embodiment, the transmission line


415


is connected at the distal end from the switch


400


to an assisting switch


905


, which is a single-pole, double-throw switch. The assisting switch


905


connects the antenna element


305


to either the transmission line


415


to receive the signal or to an inductive element


910


. When coupled to the inductive element


910


, the antenna element


305


has an effective length increase, causing the antenna element


305


to be in the reflective mode. This effective length increase makes the antenna element


305


appear as a reflective antenna element


105


(FIG.


1


), as described in reference to the Yagi antenna.




The extra switches


905


and inductive elements


910


assist the feed network in coupling the antenna elements


305


to an inductive element, rather than using the transmission line


415


in combination with the open circuit of the central switch


400


to provide the inductance. The assisting switch


905


is used, in particular, when the central switch


400


is lossy or varies in performance from port-to-port when open circuited. A typical assisting switch


905


has a −0.5 dB loss, which is more efficient than the −3 dB loss of the central switch


500


(FIG.


5


).




It should be understood that, though an inductive element


910


is shown, the inductive element can be any form of impedance, predetermined or dynamically varied. Impedances can be a delay line or lumped impedance where the lumped impedance, includes inductive and/or capacitive elements. It should also be understood that the assisting switches


905


, as in the case of the central switch


400


, can be solid state switches, micro-electro machined switches (MEMS), pin diodes, or other forms of switches that provide the open and closed circuit characteristics required for active and passive performance characteristics by the antenna elements


305


.





FIG. 10

is an alternative embodiment of the antenna assembly


215


of FIG.


3


. In this embodiment, the same five antenna elements


305


are included on the base


310


. This embodiment also includes a longer antenna element (antenna O)


1000


, which is used for omni-directional mode. To allow for the omni-directional mode, the switch


400


includes a sixth terminal to which antenna O is connected. When the signal is provided to antenna O, the other antenna elements


305


are in reflective mode. Although the other antenna elements


305


are in reflective mode, the extended length of the omni-directional antenna, antenna O, facilitates transmitting and receiving signals over the other antenna elements


305


. Antenna O may be telescoping, so as to allow a user to keep antenna O short unless omni-directional mode is desired.





FIG. 11

is an alternative embodiment of the antenna assembly


215


(

FIG. 3

) that may be operated by teachings of the present invention. Here, an antenna assembly


1100


is formed in the shape of a rectangular assembly


1102


. The antenna elements


305


are located vertically on the sides of the assembly


1102


. Transmission lines


1120


each have the same length and 50-ohm impedance and electrically connect the antenna elements


305


to fixed combiners


1125


. Through another pair of transmission lines


1130


that have 50-ohm impedances, the fixed combiners


1125


are electrically connected to a single-pole, single-throw switch


1135


.




The switch


1135


is controlled by a control signal


1145


and transmits RF signals


1140


to, or receives RF signals


1140


from, the antenna elements


305


.




Rather than having a single antenna element connected to the switch


1135


, the embodiment of

FIG. 11

has the antenna elements


305


arranged in two arrays: one array on the front of the assembly


1102


and a second array on the rear of the assembly


1102


. In operation, the switch


1135


determines which array of antenna elements


305


is in reflective mode and which array is in active mode. As depicted, the antenna elements on the front of the assembly


1102


are active elements


1110


, and the antenna elements


305


on the rear of the assembly


1102


are passive elements


1105


. The arrays are separated by, for example, one-quarter wavelengths, thus electromagnetically coupling the active elements


1110


and passive elements


1105


together to cause the passive elements


1105


to re-radiate electromagnetic energy. As indicated, the passive antenna elements


1105


have effective elongation


1115


above and below the assembly


1102


recall the Yagi antenna


100


(FIG.


1


).




It should be understood that the switch


1135


has the same performance characteristics as the central switch


40


, as described above. Further, similar feed network arrangements as those described above could be employed in the embodiment of

FIG. 12

without departing from the principles of the present invention. Also, it should be noted that (i) the transmission lines


1120


spanning between the antenna elements


305


and the fixed combiners


1125


are the same lengths and (ii) the transmission lines


1130


spanning from the switch


1135


to the fixed combiners


1125


are the same lengths. In this way, the antenna patterns fore and aft of the assembly


1100


are the same, both when the antenna elements on the front of the assembly


1100


are active and when the antenna elements


305


at the back of the assembly


1100


are active.





FIG. 12

is a flow diagram of an embodiment of a process


1200


used when operating the directive antenna


215


. The process


1200


begins in step


1205


. In step


1210


, the process


1200


determines if a control signal has been received. If a control signal has been received, then, in step


1215


, the process


1200


, in response to the control signal, selects the state of one of the antenna elements


305


, or antenna assemblages in an embodiment such as shown in

FIG. 11

, to be in an active state while the other antenna elements


305


are in a passive state. In the passive state, the antenna elements


305


are electrically coupled to a predetermined impedance and electromagnetically coupled to the active antenna element, thereby enabling the active antenna. If, in step


1210


, the process


1200


determines that a control signal has not been received, the process


1200


loops back to step


1210


and waits for a control signal to be received.




The process


1200


and the various mechanical and electrical embodiments described above are suitable for use with high data rate networks having greater than 50 kbits per second data transfer rates. For example, the high data rate network may use an CDMA2000, 1eV-DO, 1Extreme, or other such protocol.




While this invention has been particularly shown and described with references to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.



Claims
  • 1. A directive antenna, comprising:plural antenna elements in an antenna assemblage; and a feed network having a plurality of switches, at least one switch to select the state of one of the antenna elements to be in an active state in response to a control signal, a subset of the plurality of switches to assist electronically coupling the other antenna elements to a predetermined impedance including a delay line or lumped impedance, to be in a passive state and electromagnetically coupled to the active antenna element, allowing the antenna assemblage to directionally transmit and receive signals.
  • 2. The directive antenna as claimed in claim 1, wherein the lumped impedance includes inductive or capacitive elements.
  • 3. The directive antenna as claimed in claim 1, wherein the switch is a solid state switch.
  • 4. The directive antenna as claimed in claim 1, wherein the switch is a micro electro machined switch (MEMS).
  • 5. The directive antenna as claimed in claim 1, wherein the antenna assemblage is circular for a 360° discrete scan in N directions, where N is the number of antenna elements.
  • 6. The directive antenna as claimed in claim 1, wherein at least one antenna element is a sub-assemblage of antenna elements.
  • 7. The directive antenna as claimed in claim 1, wherein the antenna elements are telescoping antenna elements.
  • 8. The directive antenna as claimed in claim 1, wherein (i) the antenna elements have adjustable radial widths or (ii) the passive antenna elements are adjustable in distance from the active antenna elements.
  • 9. The directive antenna as claimed in claim 1, wherein the predetermined impedance is selectable from among plural predetermined impedances.
  • 10. The directive antenna as claimed in claim 9, wherein the selectable predetermined impedances are composed of impedance components switchably coupled to the antenna elements, wherein the impedance components include a delay line, lumped impedance, or combination thereof.
  • 11. The directive antenna as claimed in claim 10, wherein the lumped impedance is a varactor, capacitor, or inductor.
  • 12. The directive antenna as claimed in claim 1, used in a high data rate network having greater than 50 kbits per second data transfer rates.
  • 13. The directive antenna as claimed in claim 12, wherein the high data rate network uses a protocol selected from a group consisting of: CDMA2000, 1eVDO, and 1Extreme.
  • 14. A method for directing a beam using a directive antenna, comprising:providing an RF signal to or receiving one from antenna elements in an antenna assemblage; and in response to a control signal for controlling the state of a plurality of switches, selecting the state of at least one of the switches to cause one of the antenna elements in the antenna assemblage to be in an active state and selecting the state of a subset of the plurality of switches to assist electrically coupling the other antenna elements to a predetermined impedance, including a delay line or lumped impedance, to be in a passive state and electromagnetically coupled to the active antenna element, allowing the antenna assemblage to directionally transmit and receive signals.
  • 15. The method as claimed in claim 14, wherein the lumped impedance includes inductive or capacitive elements.
  • 16. The method as claimed in claim 14, wherein selecting one of the antenna elements includes operating a switch.
  • 17. The method as claimed in claim 16, wherein the switch is a solid state switch, non-solid state switch, or MEMS technology switch.
  • 18. The method as claimed in claim 14, wherein selecting one of the antenna elements includes selecting a direction from among 360° of discrete directions in N directions, where N is the number of antenna elements.
  • 19. The method as claimed in claim 14, wherein at least one antenna element is a sub-assemblage of antenna elements.
  • 20. The method as claimed in claim 14, further including telescoping the antenna elements.
  • 21. The method as claimed in claim 14, further including adjusting the width of the antenna elements (i) in radial size or (ii) in distance of the passive antenna elements from the active antenna element.
  • 22. The method as claimed in claim 14, further including selecting the predetermined impedances.
  • 23. The method as claimed in claim 22, wherein selecting the predetermined impedances includes coupling the antenna elements to a delay line, lumped impedance, or combination thereof.
  • 24. The method as claimed in claim 23, wherein the lumped impedance includes a varactor, capacitor, or inductor.
  • 25. The method as claimed in claim 14, used in a high data rate network having greater than 50 kbits per second data transfer rates.
  • 26. The method as claimed in claim 25, wherein the high data rate network uses a protocol selected from a group consisting of: CDMA2000, 1eV-DO, and 1Extreme.
  • 27. Apparatus for directing a beam using a directive antenna, comprising:plural antenna elements in an antenna assemblage; and means for selecting the state of one of the antenna elements in the antenna assemblage to be in an active state in response to a control signal, the other antenna elements being in a passive state, electrically coupled to a predetermined impedance including a delay line or lumped impedance and electromagnetically coupled to the active antenna element, allowing the antenna assemblage to directionally transmit and receive signals.
  • 28. An antenna apparatus for use with a subscriber unit in a wireless communication system, the antenna apparatus comprising:a plurality of antenna elements in an antenna assemblage; and a plurality of switches each respectively coupled to one of the antenna elements and a predetermined impedance including a delay line or lumped impedance, the switches being independently selectable to enable a respective antenna element to change between an active mode and a reflective mode enabling the antenna assemblage to directionally transmit and receive signals.
RELATED APPLICATION(S)

This application claims the benefit of U.S. Provisional Application No. 60/234,610, filed on Sep. 22, 2000, the entire teachings of which is incorporated herein by reference.

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Provisional Applications (1)
Number Date Country
60/234610 Sep 2000 US