Triple stagger offsetable azimuth beam width controlled antenna for wireless network

Abstract

A variably controlled stagger antenna array architecture is disclosed. The array employs a plurality of driven radiating elements that are spatially arranged having each radiating element or element groups orthogonally movable relative to a main vertical axis. This provides a controlled variation of the antenna array's azimuth radiation pattern without excessive side lobe radiation over full range of settings.

Claims

1. An antenna for a wireless network, comprising a generally planar reflector; a plurality of radiators in a vertical column relative to the reflector wherein a first plurality of the radiators and a second plurality of the radiators are linearly displaceable horizontally with respect to each other and with respect to a third plurality of radiators that is fixed along the vertical column; and one or more mechanical actuators coupled to the first plurality of the radiators and the second plurality of radiators to provide linear horizontal displacement of the first plurality of the radiators and the second plurality of the radiators, apart or toward each other; wherein the plurality radiators are reconfigurable horizontally from a first configuration where the radiators are all aligned in the vertical column, to a second configuration where the radiators are configured in three columns, each column having plural radiators generally aligned.

2. The antenna of claim 1, wherein the first plurality of radiators and the second plurality of radiators are movable in opposite directions.

3. The antenna of claim 1, further comprising a first plurality of radiator mount plates coupled to the first plurality of radiators and slidable relative to the reflector and a second plurality of radiator mount plates coupled to the second plurality of radiators and slidable relative to the reflector.

4. The antenna of claim 3, wherein said reflector has a plurality of orifices and wherein said first plurality of radiator mount plates and second plurality of radiator mount plates are configured behind said orifices.

5. The antenna of claim 1, wherein the reflector is generally planar defined by a Y-axis and a Z-axis parallel to the plane of the reflector and an X-axis extending out of the plane of the reflector, and wherein the radiators are spaced apart a distance VS in the Z direction.

6. The antenna of claim 5, wherein the reflectors in the first configuration are aligned along a center line parallel to the Z-axis of the reflector.

7. The antenna of claim 6, wherein the radiators in the second configuration are offset in opposite Y directions from the center line by a distance HS.sub.1 and HS.sub.2 respectively.

8. The antenna of claim 7, wherein the radiators are spaced apart by a stagger distance (SD) defined by the following relationship: SD=√{square root over (HS.sup.2+VS.sup.2)}where HS=HS.sub.1 HS.sub.2.

9. The antenna of claim 1, further comprising a multipurpose port coupled to the one or more actuators to provide beam width control signals to the antenna.

10. The antenna of claim 1, further comprising a signal dividing—combining network for providing RF signals to the plurality of radiators wherein the signal dividing—combining network includes a phase shifting network for controlling elevation beam tilt by controlling relative phase of the RF signals applied to the plurality of radiators.

11. A mechanically variable beam width antenna, comprising: a generally planar reflector; a first plurality of linearly horizontally displaceable radiators configured in a first column adjacent the reflector; a second plurality of linearly horizontally displaceable radiators configured in a second column adjacent the reflector; a third plurality of radiators configured in a fixed third column adjacent the reflector; at least one mechanical actuator coupled to the first plurality of radiators and the second plurality of radiators, the at least one mechanical actuator to provide linear horizontal displacement of the at least some of the radiators, apart or toward each other with respect to the third column, wherein the first plurality of radiators and the second plurality of radiators are movable relative to each other horizontally wherein radiators are arranged in a line from a first configuration wherein the first and second columns are spaced a first distance apart, to a second configuration wherein the first and second columns are spaced a second distance apart.

12. The antenna of claim 11, further comprising a multipurpose port coupled to the at least one actuator to provide beam width control signals to the antenna.

13. The antenna of claim 11, further comprising a signal dividing—combining network for providing RF signals to the plurality of radiators wherein the signal dividing—combining network includes a phase shifting network for controlling elevation beam tilt by controlling relative phase of the RF signals applied to at least some of the radiators.

14. The antenna of claim 11, wherein the first plurality of radiators and the second plurality of radiators are configured in rows aligned perpendicularly to said columns and the third plurality of radiators are offset from the rows of the first plurality of radiators and the second plurality of radiators.

15. The antenna of claim 13, wherein the columns comprising the first plurality of radiators and the second plurality of radiators are spaced apart a distance HS and the orthogonal offset between the first plurality of radiators and the second plurality of radiators and the third plurality of radiators is VS, and a stagger distance (SD) between the first plurality of radiators and the second plurality of radiators and the third plurality of radiators is defined by the following relationship: $\mathrm{SD}=\sqrt{{\left(\frac{\mathrm{HS}}{2}\right)}^2+{\mathrm{VS}}^2}.$

16. The antenna of claim 11, further comprising a first plurality of radiator mount plates coupled to the first plurality of radiators and slidable relative to the reflector and a second plurality of radiator mount plates coupled to the second plurality of radiators and slidable relative to the reflector, wherein pairs of first and second mount plates are coupled to a common actuator.

17. A method of adjusting signal beam width in a wireless antenna having a plurality of radiators at least some of which are movable in a direction generally parallel to a plane of a reflector, the method comprising: providing the plurality of radiators in a first configuration where the radiators are all aligned in a single column generally parallel to the reflector axis to provide a first signal beam width; and adjusting a first plurality of the radiators and a second plurality of the radiators by mechanical actuators configured to provide linear horizontal displacement to the first plurality of the radiators and to a second plurality of the radiators, in a linear horizontal direction that is generally orthogonal to the axis of the column, to a second configuration wherein the plurality of radiators are configured in at least three separate columns of plural radiators to provide a second signal beam width.

18. The method of claim 17, further comprising providing at least one beam width control signal for remotely controlling the position setting of the plurality of radiators.

19. The method of claim 17, wherein in the first configuration all of the plurality of radiators are aligned with a center line of the reflector and wherein in the second configuration alternate ones of the plurality of radiators are offset from the center line of the reflector in opposite directions.

20. The method of claim 17, further comprising providing variable beam tilt by controlling the phase of the RF signals applied to the plurality of radiators through a remotely controllable phase shifting network.

21. A method of adjusting signal beam width in a wireless antenna having a plurality of radiators at least some of which are movable in a direction generally parallel to a plane of a reflector, the method comprising: providing the plurality of radiators in a first configuration wherein the plurality of radiators are aligned in at least three separate columns of plural radiators to provide a first signal beam width; and adjusting at least some of the plurality of radiators by mechanical actuators configured to provide linear horizontal displacement to the at least some of the plurality of radiators, in a horizontal direction that is generally orthogonal to the axis of the columns to a second configuration, wherein the plurality of radiators are configured in at least three separate columns of plural radiators and wherein at least two of the columns have a different spacing between the axes of the columns than in said first configuration, to provide a second signal beam width.

22. The method of claim 21, wherein the at least three separate columns of plural radiators comprise first and second columns configured with rows of radiators aligned generally orthogonal to the axis of the columns.

23. The method of claim 22, wherein the at least three separate columns of plural radiators further comprise a third column of radiators with radiators offset in a direction orthogonal to the rows of radiators comprising said first and second columns.

24. The method of claim 23, wherein the radiators comprising said first and second columns are movable relative to each other in the direction of said rows.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1A is a front view of a dual polarization, triple column antenna array in narrow azimuth beam width setting in accordance with a first embodiment of the invention.

(2) FIG. 1B is a front view of a dual polarization, triple column antenna array in narrow azimuth beam width setting in accordance with a second embodiment of the invention.

(3) FIG. 2A is a front view of a dual polarization, triple column antenna array in wide azimuth beam width setting in accordance with a first embodiment of the invention.

(4) FIG. 2B is a front view of a dual polarization, triple column antenna array in wide azimuth beam width setting in accordance with a second embodiment of the invention.

(5) FIG. 3A and FIG. 3B provide cross sectional view details along A-A datum detailing the motion of a dual polarized antenna element corresponding to a wide (FIG. 2A) and narrow (FIG. 1A) azimuth beam width setting, respectively.

(6) FIG. 3C is a back side view of the area immediate about the third radiating element with movable plate positioned as depicted in FIG. 3B.

(7) FIG. 4A and FIG. 4B provide cross sectional view details along B-B datum detailing the motion of a dual polarized antenna element corresponding to a wide (FIG. 2A) and narrow (FIG. 1A) azimuth beam width setting, respectively.

(8) FIG. 4C is a back side view of the area immediate about the fifth radiating element with movable plate positioned as depicted in FIG. 4B.

(9) FIG. 5 is an RF circuit diagram of an antenna array equipped with a Phase Shifter and Power Divider.

(10) FIG. 6A and FIG. 6B provide cross sectional view details along C-C datum detailing the motion of a dual polarized (second embodiment) antenna element corresponding to a wide (FIG. 2B) and narrow (FIG. 1B) azimuth beam width setting, respectively.

(11) FIG. 6C is a back side view of the area immediate about a radiating element with movable plate positioned as depicted in FIG. 6B.

(12) FIG. 7 is a simulated azimuth radiation pattern of an antenna (first embodiment) configured for narrow azimuth beam width (FIG. 1A).

(13) FIG. 8 is a simulated azimuth radiation pattern of an antenna (first embodiment) configured for wide azimuth beam width (FIG. 2A).

(14) FIG. 9 is a simulated azimuth radiation pattern of an antenna (second embodiment) configured for narrow azimuth beam width (FIG. 1B).

(15) FIG. 10 is a simulated azimuth radiation pattern of an antenna (second embodiment) configured for wide azimuth beam width (FIG. 2B).

DETAILED DESCRIPTION OF THE INVENTION

(16) Reference will be made to the accompanying drawings, which assist in illustrating the various pertinent features of the present invention. The present invention will now be described primarily in solving aforementioned problems relating to use of plurality of mechanical phase shifters, it should be expressly understood that the present invention may be applicable in other applications wherein azimuth beam width control is required or desired.

(17) First Embodiment

(18) FIG. 1A shows a front view of a dual polarization, triple column antenna array, 100, according to a first exemplary implementation of the invention. The array utilizes a conventionally disposed reflector 105. Reflector, 105 is oriented in a vertical orientation (Z-dimension) of the antenna array. The reflector, 105, may, for example, consist of an electrically conductive plate suitable for use with Radio Frequency (RF) signals. Further, reflector 105, plane is shown as a featureless rectangle, but in actual practice additional features (not shown) may be added to aid reflector performance.

(19) Continuing with reference to FIG. 1A an antenna array, 100, contains a plurality of RF radiating (110, 120, 130, 140-to-250) elements preferably arranged both vertically and horizontally in a triple column arrangement along three operationally defined vertical axis. The left most axis, P1, provides horizontal alignment movement limit to shiftable plates 154, (114, 194, 234 are not shown) operationally disposed below the forward facing surface of the reflector 105 in the corresponding reflector orifices 153, (113, 193, 233 are not shown). The right most axis, P2, provides horizontal alignment movement limit to shiftable plates 134, (174, 214, 254 not shown) operationally disposed below the forward facing surface of the reflector 105 in the corresponding reflector orifices 133, (173, 213, 253 not shown). Centrally disposed axis, PO, is co-aligned with vertical center line CL of the reflector 105. In this particular embodiment RF radiating elements (120, 140, 160, 180, 200, 220, 240) are vertically aligned about P0 axis and are not equipped with horizontal movement capability. It is possible to implement the antenna array wherein centrally disposed radiating elements (120,140,160,180, 200, 220,240) can be horizontally moveable thus allowing enhanced beam width shape control.

(20) Referring to FIGS. 3A-3C, right most RF radiating 130 element (or RF radiator for short) is mounted on corresponding feed-through mount 132 centrally disposed on a top surface of a shiftable foundation mount plate 134 capable of controllable orthogonal (horizontal) movement relative to the main vertical axis P0 limited by the peripheral dimensions of the corresponding reflector orifices 133. The maximum right most displacement of the radiating element 130 is is defined by limit axis P2 and traversal distance HS2. In addition to radiator 130, radiators 170, 210, and 250 are similarly equipped and are mounted on corresponding feed-through mounts (not shown 172, 212, 252) centrally disposed on a top surface of a shiftable foundation mount plate (not shown 174, 214, 254, 234) exhibiting identical controllable orthogonal movement relative to the main vertical axis limited by the peripheral dimensions of the corresponding reflector orifices (not shown 173, 213, 253). Details pertaining to movable foundation mount plate 114 and relating structures will become apparent upon examination of FIGS. 3A, B and C.

(21) Referring to FIGS. 4A-4C, left most RF radiator 150 is similarly mounted on corresponding feed-through mount 152 centrally disposed on a top surface of a shiftable foundation mount plate 154 capable of controllable orthogonal movement relative to the main vertical axis limited by the peripheral dimensions of the corresponding reflector orifices 153. The maximum left most displacement of the radiating element 150 is defined by limit axis P1 and traversal distance HS1. In addition to radiator 150 radiators 110, 190, and 230 are similarly equipped and are mounted on corresponding feed-through mounts (not shown 112, 192, 232) centrally disposed on a top surface of a shiftable foundation mount plate (not shown 114, 194; 234) exhibiting identical controllable orthogonal movement relative to the main vertical axis limited by the peripheral dimensions of the corresponding reflector orifices (not shown 113, 293, 233). Details pertaining to movable foundation mount plate 154 and relating structures will become apparent upon examination of FIGS. 4A, B and C.

(22) In an antenna system 100 configured for a broad beam width radiation pattern, the RF radiators are preferably aligned along the common vertical axis labeled P.sub.0 and are separated vertically by a distance VS. Preferably, the common axis P.sub.0 is the same as center vertical axis of the reflector 105, plane. Such a broad beam width configuration is illustrated in FIG. 2A. Alignment axis P.sub.0 is equidistant from the vertical edges of the of the reflector 105, plane. For this nominal configuration stagger distance (SD) is defined by the following relationship:
SD=VS

(23) For a narrow beam width azimuth radiation pattern left group RF radiators (110, 150, 190, and 230) are positioned at leftmost alignment position and right group (130, 170, 210, and 250) are positioned as shown in FIG. 1A. This position is characterized by stagger distance (SD) which for a particular setting can be defined by the following relationship:
SD=√{square root over (HS.sup.2+VS.sup.2)} where HS=HS.sub.1=HS.sub.2

(24) Through computer simulations and direct EM field measurement it was determined that the azimuth radiation beam pattern can be deduced from the above formula. By varying HS dimension desired azimuth beam width settings can be attained. VS dimension is defined by the overall length of the reflector 105 plane which defines the effective antenna aperture. In the illustrative non-limiting implementation shown, RF radiator, 105, together with a plurality of folded dipole (110, 120, 130, 140 -to- 250} radiating elements form an antenna array useful for RF signal transmission and reception. However, it shall be understood that alternative radiating elements, such as taper slot, horn, aperture coupled patches (APC), and etc, can be used as well.

(25) A cross section datum A-A and B-B will be used to detail constructional and operational aspects relating to radiating elements relative movement. Drawing details of A-A datum can be found in FIG. 3A and FIG. 3B.

(26) FIGS. 3A and 3B provide cross sectional views along A-A datum. A-A datum, as shown in FIG. 1A, bisects right side movable radiating element 130 and is associated mechanical structures. FIG. 3C provides a back side view of the area immediate of the third radiating element 130. It shall be understood that all right side movable radiating elements share similar construction features, details being omitted for clarity. As shown in FIG. 3A a vertically polarized radiating element 130 is mounted with a feed-through mount 132. A feed through mount 132 is preferably constructed out of a dielectric material and provides isolation means between radiating element 130 and movable plate 134. Movable plate 134 is preferably constructed utilizing a rigid material as long as the plate's top surface is comprised of highly conductive material, but alternatively can be constructed from aluminum plate and the like. The RF signal is individually supplied from a power dividing-combining network 310 with a suitable flexible radio wave guide 139, such as flexible coaxial cable, and coupled to conventionally constructed feed through mount terminals 132 (details are not shown).

(27) Movable foundation mount plate 134 is recessed, and mounted immediately below the bottom surface of radiator 105 plane and supported with a pair of sliding 137 guide frames, on each side reflector orifice 133, having u-shape slots 138 which provide X (vertical) dimensional stability while providing Y (horizontal when viewed from front of the antenna) dimensional movement for the movable foundation mount plate 134. As shown in FIG. 3C the back side of the movable foundation mount plate 134 and associated sliding guide frames 137 which are used for support are enclosed with a suitably constructed cover 135 to prevent undesirable back side radiation and to improve the front to back signal ratio. Actuator 300 provides mechanical motion means to the jack screw 131. Jack screw rotation is coupled to a mechanical coupler 136 attached to the back side movable foundation mount plate 134. By controlling direction and duration of rotation of the jack screw 131 subsequently provides Y dimensional movement to the movable foundation mount plate 134. As will be appreciated by those skilled in the art jack screw 131 is one of many possible means to achieve Y-dimensional movement to the movable foundation mount plate 134. The mechanical actuator 300, or other well known means, may be extended to provide mechanical motion means to other or preferably all other right side jack screws 131, 171, 211, and 251 used to control motion of respective radiating elements 130,170,210, and 250.

(28) The above description outlines basic concepts covering right side radiating element group (130, 170, 210 & 250), but it shall be understood that basic building elements are replicated for left hand side radiating element group (110, 150, 190, 230) as well, while incorporating appropriate directional changes to accommodate element movement relative to the centerline Po—In some instances it maybe advantageous to combine or perhaps mirror mount mechanical assemblies into a single device as deemed appropriate for the application.

(29) It is also possible to provide an antenna element position configuration such that HS.sub.1≠HS.sub.2. Such configuration is possible since right side jack screw 300 and left side jack screw 305 are independently controlled. Resultant antenna array azimuth pattern may exhibit a desirable pattern skew which can be altered based on operational requirements.

(30) With reference to FIG. 5 RF radiator elements (11 0, 120, 130, 140, -to-250) are fed from a master RF input port, 315, with the same relative phase angle RF signal through a conventionally designed RF power signal dividing—combining network 310. RF power signal dividing—combining network 310 output-input ports 310(a-o) are coupled via suitable radio wave guides (119, 129, 139, 149-to-259), such as coaxial cable to corresponding radiating elements (110, 120, 130, 140 -to-250). In some operational instances such RF power signal 310 dividing-combining network may include a remotely controllable phase shifting network so as to provide beam tilting capability as described in U.S Pat. No. 5,949,303 assigned to current assignee and incorporated herein by reference in its entirety. An example of such an implementation is shown in FIG. 5 wherein RF signal dividing—combining network 310 provides an electrically controlled beam downtilt capability. Phase shifting function of the power dividing network 310 may be remotely controlled via multipurpose control port 320. Similarly, azimuth beam width control signals are coupled via multipurpose control port 320 to left 300 and right 305 side mechanical actuators. Since each side mechanical actuators are individually controlled it possible to set the amount of element displacement differently. This provides advantageous means for radiation pattern skewing and azimuth beam width control.

(31) As was described hereinabove a plurality of radiating elements (11 0, 120, 130, 140, -to-250) together form an antenna array useful for RF signal transmission and reception.

(32) Consider the following two operational conditions (a-b):

(33) Operating condition (a) wherein all RF radiators (110,120, 130, 140-to-250), as depicted in FIG. 2A, are aligned about Po axis which is proximate to vertical center axis of the reflector 105 plane. Such alignment setting will result in a relatively wide azimuth beam width as shown in the simulated pattern of FIG. 7.

(34) Operating condition (b) wherein RF radiators (110, 120, 130,140,) as depicted in FIG. 1A, are positioned in the following configuration: The left side group of RF radiators 110, 150,190, and 230 are positioned along P.sub.1 axis and right group of RF radiators 130, 170, 210, 250 are positioned along P.sub.2 axis. The resultant azimuth radiation beam width will be narrower when compared to (a). Such alignment setting will result in a relatively wide azimuth beam width as shown in the simulated pattern of FIG. 8. Obviously, HS.sub.1 and HS.sub.2 can be varied continuously from a minimum (0) to a maximum value to provide continuously variable azimuth variable beam width between two extreme settings described hereinabove. It is possible to achieve azimuth HBW from 30 to 90 degrees while utilizing relatively small sized reflector width commonly used with non adjustable antennas. Narrower HBW azimuths can be achieved with wider size reflector 105 and increased HS1 and HS2 dimensions.

(35) Second Embodiment

(36) FIG. 1B shows a front view of a dual polarization, triple column antenna array, 101, according to an exemplary implementation of the invention in accordance with a second embodiment. The array utilizes a conventionally disposed reflector 105. Reflector, 105 is oriented in a vertical orientation (Z-dimension) of the antenna array. The reflector, 105, may, for example, comprise an electrically conductive plate suitable for use with RF signals. Further, reflector 105, plane is shown as a featureless rectangle, but in actual practice additional features (not shown) may be added to aid reflector performance.

(37) Continuing with reference to FIG. 1B an antenna array, 101, contains a plurality of horizontally displaceable RF radiating element pairs (110A-110B, 130A-130B, -to-250A-250B) preferably arranged both vertically and horizontally, in a dual column arrangement along operationally defined vertical axis P1 and P2. In between horizontally moveable element pairs, fixed radiating elements 120, 140, 160, 180, 200, 220, 240 are placed along vertical centerline axis P0. Each horizontally displaceable RF radiating element pair (110A-110B, 130A-130B, -to-250A-250B) is provided with displacement means to provide equidistant motion for its individual radiating elements 110A and 110B.

(38) In reference to FIGS. 6A and 6B right mounted RF radiating element 110A is mounted with feed-through mount 411 on top of right moveable plate 413. Similarly, right mounted RF radiating element 110B is mounted with feed-through mount 412 on top of right moveable plate 414. Both left 413 and right 414 plates are operationally disposed below the forward facing surface of the reflector 105 in the reflector orifice 113. Electrically conductive filler panel 410 is used to bridge variable gap between the left 413 and right 414 moveable plates to prevent ground discontinuity as the two moveable plates are moved apart or toward each other horizontally and equidistantly about the center axis P0. A suitable mechanical actuator 302 is provided to provide equidistant horizontal displacement about antenna array center axis P0.

(39) Movable foundation mount left 413 and right 414 plates are recessed, and mounted immediately below the bottom surface of radiator 105′ plane and supported with a pair of sliding 117 guide frames, on top and bottom sides of reflector orifice 133, having u-shape slots 118 which provide X (vertical) dimensional stability while providing Y (horizontal when viewed from front of the antenna) dimensional movement for the movable foundation mount plates 413 and 414. In FIG. 6C the back side of the movable foundation plates and associated sliding guide frames 117 are covered with suitably constructed back cover 115 to prevent undesirable back side radiation and to improve the front to back signal ratio.

(40) Mechanical actuator 302 is equipped with left 415 and right 416 jack screws to provide equidistant displacement about center axis to corresponding left 413 and right 414 moveable plates. Left 415 and right 416 jack screws are operationally coupled via left 419 and right 420 rotation to linear displacement couplers that are attached to corresponding left 413 and right 414 moveable plates. Altering jack screw rotation effectively changes the direction of travel for both RF radiating element 110A-B in unison such that both RF radiating elements 110A and 110B are equidistant about center axis P0. It should be readily apparent to those skilled in the art that the jack screw arrangement can be replaced with any alternative mechanical actuator suitably adapted for this purpose.

(41) Net horizontal displacement of RF radiating elements 110A-B is measured between feed through (411, 412) centerlines min<H.sub.s<, max where, for antenna system design to operate between 1.7 to 2.1 GHz min=90 mm and max=190 mm. Movable RF radiating elements stagger distance (SD) for a particular setting can be defined by the following relationship:

(42) $\mathrm{SD}=\sqrt{{\left(\frac{\mathrm{HS}}{2}\right)}^2+{\mathrm{VS}}^2}$

(43) Through computer simulations and direct EM field measurement it was determined that the azimuth radiation beam pattern can be deduced from above formula.

(44) RF radiating elements 110A-B are provided with corresponding RF feed lines 417 and 418. In downlink transmission mode the RF signal, from power combiner—divider network 310, is delivered from port 310a to a conventional in phase 3 dB divider (not shown) network having its first output port coupled left side feed line 417 and second output port coupled right side feed line 418. In uplink receiving mode RF signals from RF radiating elements 110A-B are delivered to corresponding—3 dB ports of a conventional in phase 3 dB divider (not shown) network having its common port coupled to port 310a of the power combiner—divider network 310. Alternatively, combiner—divider network 310 can be modified to provide required coupled ports with necessary networks.

(45) Consider the following two operational conditions (c-d):

(46) Operating condition (c) wherein all RF radiators (110A-B, 130A-B, -to-250A-B), as depicted in FIG. 2B, are aligned about corresponding P.sub.1 and P.sub.2 axis such that HS=minimum. Such an alignment setting will result in a relatively wide azimuth beam width as shown in the simulated pattern of FIG. 9.

(47) Operating condition (d) wherein all RF radiators (110A-B, 130A-B, to 250A-B), as depicted in FIG. 1B, are aligned about corresponding P.sub.1 and P.sub.2 axis such that HS=maximum. Such an alignment setting will result in a relatively narrow azimuth beam width as shown in the simulated pattern of FIG. 10. The resultant azimuth radiation beam width will be narrower when compared to (c). Obviously, HS can be varied continuously from a minimum to a maximum value to provide continuously variable azimuth variable beam width between the two extreme settings described hereinabove. It is possible to achieve azimuth HBW from 30 to 90 degrees. As in the first embodiment it is possible to achieve azimuth HBW from 30 to 90 degrees while utilizing relatively small sized reflector width commonly used with non adjustable antennas. Further narrowing of the HBW azimuth angle can be achieved with wider size reflector 105 and increased HS dimension.

(48) The foregoing description is presented for purposes of illustration and description. Furthermore, the description is not intended to limit the invention to the form disclosed herein. Accordingly, variants and modifications consistent with the following teachings, and skill and knowledge of the relevant art, are within the scope of the present invention. The embodiments described herein are further intended to explain modes known for practicing the invention disclosed herewith and to enable others skilled in the art to utilize the invention in equivalent, or alternative embodiments and with various modifications considered necessary by the particular application(s) or use(s) of the present invention.