1. Field of the Invention
The present invention relates in general to communication systems and components. More particularly the present invention is directed to antenna arrays for cellular communications systems.
2. Description of the Prior Art and Related Background Information
Modern wireless antenna implementations generally include a plurality of radiating elements that may be arranged over a reflector plane defining a radiated (and received) signal beam width and azimuth scan angle. Azimuth antenna beam width can be advantageously modified by varying amplitude and phase of an RF signal applied to respective radiating elements. Azimuth antenna beam width has been conventionally defined by Half Power Beam Width (HPBW) of the azimuth beam relative to a bore sight of such antenna array. In such an antenna array structure radiating element positioning is critical to the overall beam width control as such antenna systems rely on accuracy of amplitude and phase angle of the RF signal supplied to each radiating element. This places severe constraints on the tolerance and accuracy of a mechanical phase shifter to provide the required signal division between various radiating elements over various azimuth beam width settings.
Real world applications often call for an antenna array with beam down tilt and azimuth beam width control that may incorporate a plurality of mechanical phase shifters to achieve such functionality. Such highly functional antenna arrays are typically retrofitted in place of simpler, lighter and less functional antenna arrays while weight and wind loading of the newly installed antenna array can not be significantly increased. Accuracy of a mechanical phase shifter generally depends on its construction materials. Generally, highly accurate mechanical phase shifter implementations require substantial amounts of relatively expensive dielectric materials and rigid mechanical support. Such construction techniques result in additional size and weight not to mention being relatively expensive. Additionally, mechanical phase shifter configurations that have been developed utilizing lower cost materials may fail to provide adequate passive intermodulation suppression under high power RF signal levels.
Consequently, there is a need to provide a simpler method to adjust antenna beam width control.
In a first aspect the present invention provides an antenna for a wireless network comprising a generally planar reflector, a plurality of radiators, and one or more actuators coupled to at least some of the radiators. The radiators are reconfigurable from a first configuration where the radiators are all aligned to a second configuration where the radiators are configured in three columns, each column having plural radiators generally aligned.
In a preferred embodiment of the antenna the plurality of radiators comprise a first and second plurality of radiators which are movable and a third plurality of radiators which are fixed. The first and second plurality of radiators are preferably movable in opposite directions. In a preferred embodiment a first plurality of radiator mount plates are coupled to the first plurality of radiators and slidable relative to the reflector and a second plurality of radiator mount plates are coupled to the second plurality of radiators and slidable relative to the reflector. The reflector preferably has a plurality of orifices and the first and second plurality of radiator mount plates are configured behind the orifices. The reflector is preferably generally planar and is 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 the radiators are spaced apart a distance VS in the Z direction. The reflectors in the first configuration are preferably aligned along a center line parallel to the Z-axis of the reflector. The reflectors in the second configuration are offset in opposite Y directions from the center line by a distance HS1 and HS2 respectively. The radiators are spaced apart by a stagger distance (SD) defined by the following relationship:
SD=√{square root over (HS2+VS2)}
where
HS=HS1+HS2.
The antenna may further comprise a multipurpose port coupled to the one or more actuators to provide beam width control signals to the antenna. The antenna may further comprise a signal dividing—combining network for providing RE 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 radiators.
In another aspect the present invention provides a mechanically variable beam width antenna comprising a generally planar reflector, a first plurality of radiators configured in a first column adjacent the reflector, a second plurality of radiators configured in a second column adjacent the reflector, a third plurality of radiators configured in a third column adjacent the reflector, and at least one actuator coupled to the first and second plurality of radiators. The first plurality of radiators and the second plurality of radiators are movable relative to each other in a direction generally parallel to the plane of the reflector 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.
In a preferred embodiment the antenna further comprises a multipurpose port coupled to the at least one actuator to provide beam width control signals to the antenna. The antenna may further comprise 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 radiators. The first and second plurality of radiators are preferably configured in rows aligned perpendicularly to the columns and the third plurality of radiators are offset from the rows of the first and second plurality of radiators. More specifically, the columns comprising the first and second plurality of radiators are spaced apart a distance HS and the orthogonal offset between the first and second plurality of radiators and the third plurality of radiators is VS. A stagger distance (SD) between the first and second plurality of radiators and the third plurality of radiators is defined by the following relationship:
The antenna may further comprise 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.
In another aspect the present invention provides 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 the reflector. The method comprises providing the 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. The method further comprises adjusting at least some of the radiators in a direction generally orthogonal to the axis of the column to a second configuration wherein the radiators are configured in at least three separate columns of plural radiators to provide a second signal beam width.
In a preferred embodiment the method further comprises providing at least one beam width control signal for remotely controlling the position setting of the radiators. In the first configuration all radiators are preferably aligned with a center line of the reflector and in the second configuration alternate radiators are offset from the center line of the reflector in opposite directions. The method may further comprise providing variable beam tilt by controlling the phase of the RF signals applied to the radiators through a remotely controllable phase shifting 5 network.
In another aspect the present invention provides 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 the reflector. The method comprises providing the radiators in a first configuration wherein the radiators are aligned in at least three separate columns of plural radiators to provide a first signal beam width. The method further comprises adjusting at least some of the radiators in a direction generally orthogonal to the axis of the columns to a second configuration, wherein the 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 the first configuration, to provide a second signal beam width.
In a preferred embodiment of the method 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. 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 the first and second columns. The radiators comprising the first and second columns are movable relative to each other in the direction of the rows.
Further features and aspects of the invention are set out in the following detailed description of the invention.
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.
First Embodiment
Continuing with reference to
Referring to
Referring to
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 P0 and are separated vertically by a distance VS. Preferably, the common axis P0 is the same as center vertical axis of the reflector 105, plane. Such a broad beam width configuration is illustrated in
SD=VS
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
SD=√{square root over (HS2+VS2)} where HS=HS1=HS2
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.
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
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
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.
It is also possible to provide an antenna element position configuration such that HS1≠HS2. 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.
With reference to
As was described hereinabove a plurality of radiating elements (110, 120, 130, 140, -to-250) together form an antenna array useful for RF signal transmission and reception.
Consider the following two operational conditions (a-b):
Operating condition (a) wherein all RF radiators (110,120, 130, 140-to-250), as depicted in
Operating condition (b) wherein RF radiators (110, 120, 130,140,) as depicted in
Second Embodiment
Continuing with reference to
In reference to
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
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.
Net horizontal displacement of RF radiating elements 110A-B is measured between feed through (411, 412) centerlines min<Hs<, 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:
Through computer simulations and direct EM field measurement it was determined that the azimuth radiation beam pattern can be deduced from above formula.
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.
Consider the following two operational conditions (c-d):
Operating condition (c) wherein all RF radiators (110A-B, 130A-B, -to-250A-B), as depicted in
Operating condition (d) wherein all RF radiators (110A-B, 130A-B, to 250A-B), as depicted in
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.
The present application claims priority under 35 USC section 119(e) to U.S. provisional patent application Ser. No. 60/934,371 filed Jun. 13, 2007, the disclosure of which is incorporated herein by reference in its entirety.
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Number | Date | Country | |
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Parent | 12157646 | Jun 2008 | US |
Child | 13917196 | US |