The present invention relates to an antenna element and to an array of antenna elements, and is particularly, but not exclusively suited to cavity-backed, slot-radiating type.
Modern wireless communications systems place great demands on the antennas used to transmit and receive signals, especially at cellular wireless base stations. Antennas are required to produce a carefully tailored radiation pattern with a defined beamwidth in azimuth, so that, for example, the wireless cellular coverage area has a controlled overlap with the coverage area of other antennas. The antennas may be deployed, for example, in a tri-cellular arrangement or, with a narrower beamwidth, as a six-sectored arrangement.
In addition to a defined azimuth beam, such antennas are also required to produce a precisely defined beam pattern in elevation; in fact the elevation beam is generally required to be narrower than the azimuth beam.
It is conventional to construct such antennas as an array of antenna elements to form the required beam patterns. Such arrays require a feed network in order to energise the antenna elements: on transmission, the feed network splits signals into components with whichever phase relationship is required to drive the antenna elements, and on reception, the feed network functions as a combiner. An array consisting of a single vertical column of antenna elements is commonly used at cellular radio base stations with a tri-cellular cell pattern. Similar arrays, but with two or more columns may be deployed if narrower azimuth beams are required. Generally, it is desirable to place antenna elements no more than approximately a half wavelength apart in azimuth at the carrier frequency under consideration to avoid generating grating lobes in the antenna pattern with associated unwanted nulls. It can be demanding to produce antenna elements physically small enough to be placed in an array on a half wavelength grid.
In addition the antenna should be capable of withstanding the environmental conditions experienced on the top of a mast, such as temperature extremes and wind loading, while being cheap to produce and light in weight to ease installation.
A design for an array antenna is described in the applicant's co-pending international patent application publication number WO 2007/031706; this design provides an antenna array having an electrically conductive tube (or cylinder), an electrically conductive outer surface, and a feed layer located between the tube and the outer surface. The antenna array is arranged to carry electrically conductive tracks, and houses dielectric material between the tube and the feed layer and between the outer surface and the feed layer. The antenna comprises a plurality of radiating elements formed as slots that are defined by areas of non-conductivity in both the front face of the outer surface and in the tube which are in registry with one another, the slots being energised in use by respective conductive tracks defined on the feed layer which are generally in registry with the slots.
In this design, the electrically conductive tube or cylinder—typically rectangular—may be made of a light weight plastics material with an electrically conductive coating with slots in the front face of the tube and ribs within the tube forming relatively closed cavities behind the slots. The tube therefore defines a relatively closed, compartmentalised but partially hollow structure. This presents some difficulty in manufacture because it is difficult to manufacture such structures as one-piece mouldings; as a result the antenna is likely to be moulded from two separate pieces, which are joined together to form the tube. This is a relatively expensive and time consuming.
It can be seen that there are many challenges to be faced when designing an antenna that produces a desired radiation pattern while being low cost and lightweight.
In accordance with a first aspect of the present invention, there is provided an antenna comprising:
an electrically conductive enclosure with a non-conducting aperture formed in an end thereof;
an electrically conductive cover comprising a first portion covering at least part of said end of the enclosure and a second portion covering at least part of a side of the enclosure;
a feed layer located between the enclosure and said first portion of the cover and arranged to carry electrically conductive track; and
a radiating element formed as a slot defined by an area of non-conductivity within said first portion of the cover, the slot being energised in use by a radiating portion of the track defined on the feed layer, said radiating portion being generally in registry with the slot,
wherein the non-conducting aperture formed in said end of the enclosure is of a larger area than that of the slot defined in the cover.
In embodiments of the invention the antenna array is provided by an enclosure with an open or partially open end and a cover with a slot; the combination of enclosure and cover provide a cavity, and the feed layer forms a cavity-backed, slot-radiating antenna element having a closed structure. In arrangements in which the aperture extends to the sides of the enclosure, a portion of the cover—namely that extending along the sides of the enclosure—forms part of the wall of the cavity. An advantage of such an arrangement is that the enclosure can be easily moulded.
In some arrangements parts of some of the walls of the enclosure include fence structures which extend beyond the plane of the aperture towards, but not abutting, the cover. Thus when assembled, there is a gap between these fence structures and an internal face of the cover; this arrangement allows capacitative coupling between the fence structure and the cover, while the fence structures themselves increase the isolation between antenna elements when combined as an array. The size of the gap contributes to the isolation provided by the fence structure, and functions to prevent passive intermodulation distortion that may be cause by contact between conducting structures.
Conveniently, a dielectric material is located within the cavity, or outside of the cavity, to allow the physical size of the enclosure to be reduced compared with an enclosure designed for operation at the same radio frequency without dielectric material located in the cavity.
Preferably, the cover is extended to protrude beyond the side walls of the enclosure so that the ground plane formed by the surface of the cover surrounding the slot is extended; this has the effect of narrowing the beam formed by the antenna. A narrower beam may be desirable in some applications, such as a tri-cellular sector antenna in a cellular wireless system.
According to a second aspect of the invention, an array of antenna elements may be formed by an enclosure with internal walls, thereby forming an array of cavities. The array is covered by a cover in which slots are formed, and the slots are energised by a feed layer between the cover and the enclosure as described above. Conveniently, the feed layer is extended so that a portion lies between the side of the enclosure and the cover. This has the benefit that radio signals can be routed through this feed layer to respective antenna elements. Conventional printed stripline components such as filters and couplers can conveniently be formed on the feed layer in this region. This has the benefit of providing a convenient means of replacing external components that would otherwise be required to form a feed network.
Preferably, a second feed layer is inserted above the first feed layer in the region between the enclosure and the cover. This can be used to form overlay couplers, that is regions of track of approximately a quarter wavelength in length that run one above the other. The benefit of an overlay coupler is that it allows connection to the feed layer without a metal-to-metal contact; since the feed layer energises the slots, avoiding metal-to-metal contact is desirable since it minimises passive intermodulation distortion and simplifies construction.
According to a further aspect of the invention, an antenna array is formed in a modular fashion, by associating multiple antenna array enclosures and associated feed networks to a single cover formed from an integral sheet. This has structural benefits since the cover provides rigidity and can typically be easily made as one piece.
a is a schematic diagram showing the position of the cross section through the single antenna element shown in
b is a schematic diagram showing a cross-section of a conventional antenna element;
c is a schematic diagram showing a cross-section of an antenna element in a first arrangement;
d is a schematic diagram showing a cross-section of an antenna element in a second arrangement;
a is a schematic diagram showing the construction of an array of antenna elements according to an embodiment of the invention with dielectric foam layer and fence structures;
b is a schematic diagram showing detail of the construction of a fence structure;
a is a schematic diagram showing an arrangement of vertically and horizontally polarised slots in a cover according to an embodiment of the invention;
b is a schematic diagram showing an arrangement slots in a cover according to an embodiment of the invention at polarisations of +/−45 degrees;
c is a schematic diagram showing a vertical and horizontal array of vertically and horizontally polarised slots in a cover according to an embodiment of the invention;
a is a schematic diagram showing a first arrangement of dielectric loading on an antenna according to an embodiment of the invention;
b is a schematic diagram showing a second arrangement of dielectric loading on an antenna according to an embodiment of the invention;
c is a schematic diagram showing a third arrangement of dielectric loading on an antenna according to an embodiment of the invention;
a is a schematic diagram showing a conductive track on an upper feed layer as part of a coupler structure;
b is a schematic diagram showing a conductive track on a lower feed layer as part of a coupler structure;
c is a schematic diagram showing conductive tracks on an upper and lower feed layer overlaid as a coupler structure;
d is a schematic diagram showing conductive tracks on an upper and lower feed layer overlaid as a coupler structure in cross-section;
a is a schematic diagram showing conductive tracks on an upper feed layer as part of a variable phase shifter structure;
b is a schematic diagram showing conductive tracks on a lower feed layer as part of a variable phase shifter structure;
c is a schematic diagram showing conductive tracks on an upper and lower feed layer overlaid as a variable phase shifter structure;
a is a schematic diagram showing conductive tracks on an upper feed layer as part of a second variable phase shifter structure;
b is a schematic diagram showing conductive tracks on a lower feed layer as part of a second variable phase shifter structure; and
c is a schematic diagram showing conductive tracks on an upper and lower feed layer overlaid as a second variable phase shifter structure.
Several parts and components of the invention appear in more than one Figure; for the sake of clarity the same reference numeral will be used to refer to the same part and component in all of the Figures. In addition, certain parts are referenced by means of a number and one or more suffixes, indicating that the part comprises a sequence of elements (each suffix indicating an individual element in the sequence). For clarity, when there is a reference to the sequence per se the suffix is omitted, but when there is a reference to individual elements within the sequence the suffix is included.
For clarity, the methods and apparatus are described in the context of an antenna system suitable for use with a cellular wireless base station. However, it is to be understood that the invention is not limited to such an application. For example, the present invention may be applied to wireless systems other than cellular systems, and the antenna elements may be used singly or as arrays of antennas in any configuration.
As the enclosure 3 may remain open on one end, the enclosure may be moulded in one piece, preferably from a plastics material which can be coated with an electrically conductive material. Alternatively, the structure may be made from electrically conductive material such as aluminium, another metal or a composite material. Preferably, the cover 1 is made from an electrically conductive material such as aluminium, another metal such as steel or a composite material. The shape of the cover is relatively easy to form from sheet material for example, by stamping and folding operations. Alternatively, the cover may be made from a plastics material which is coated with an electrically conductive material.
An antenna 4 formed from the structure 3, feed layer 2 and cover 1 may define a single antenna module 4 for an antenna array comprising two or more such modules 4. A module may consist of any number of antenna elements; the choice of number of elements may be influenced by such factors as limitations in manufacturing technology in producing a module above a certain size, and indeed on the number of elements required in antenna array. Antenna modules may be fixed together to form arrays of antennas having virtually any two-dimensional arrangement of antenna elements. Indeed, in some arrangements a three dimensional arrangement may be desired. Preferably, fixing elements are used to permit easy assembly of antenna arrays together. The fixing elements on one module cooperate with those on another to fix the modules in place with each other. Fixings need not be electrically conductive; in many cases it is sufficient that the box structures are capacitatively coupled together by means of gaps of less than approximately a millimeter between adjacent faces of the box structures.
The feed network for the radiating slot elements can be formed from electrically conductive stripline tracks on a plastic (for example Mylar) layer 2 that is sandwiched between the cover 1 and the structure 3. In international patent application having publication number WO 2007/031706 (introduced above) the electrically conductive feed elements form T-bars within the dog-bone shaped slots. In embodiments of the present invention, the feed element 6 within the slot 5 is linear and is preferably oriented perpendicular to a longest side of the rectangular slot 5. The feed element 6 can be in registration with the slot 5 and is arranged to have suitable dimensions and position to match the electrical impedance of the feed network to the slot. Such a feed structure improves the efficiency of energy transmission to the cavities.
In preferred arrangements, the end walls and any internal walls of the structure extend slightly beyond the plane of the open side of the box. These extensions are known as fence structures 10 as shown in
By limiting protrusions to the end and internal walls, access for the feed network can be provided in the feed layer over the side walls. Whilst this is a preferred arrangement, it will be appreciated that the fence structures 10 may be provided in any of the walls of the structure, provided they are configured so as to allow access for the feed network in the feed layer.
The purpose of the deliberate gap is to minimise the generation of passive intermodulation products (PIM). PIM can potentially cause radio interference and non-linear effects, especially but not only in frequency duplexed systems. PIM occurs when an electrical connection is not firmly made, and can, for example, be caused by an oxide layer existing between the conductors. This positioning requirement can be achieved by the fence structure being either secured relative to the cover, for example by screw fixings, or else maintaining a small gap as shown in
Alternatively, as shown in
a illustrates the plane AA-BB in respect of which cross-sections of a single antenna element are shown in
As a further embodiment, a plurality of antenna elements may be combined in a structure as shown in
a illustrates the application of a fence structure 10 to a four element antenna array 70. Preferably, only a smaller cross section of the end and internal walls are extended by means of fence structures, as illustrated by
As described above, the extensions provided by the fence structures 10 serve to provide increased RF isolation between adjacent cavities (whether in the same antenna module or between antenna elements in adjacent modules) which improves efficiency and performance.
As has been discussed, the slots 5a . . . 5d in the cover may be alternate vertical (V) and horizontal (H) slots thereby forming cross-polar antenna elements. Alternatively, the slots may be a +45 degrees and −45 degrees to the vertical or at other orientations. The slots may be rectangular lozenge shaped. Where cavities of the structure form open rectangular boxes, the slots of the cover when fitted will be parallel to the side or end/internal walls of the open rectangular box cavities.
a,
The spacing between slots in azimuth is relevant to the operation of the array. Many arrays require a spacing of as little as half a wavelength at the radiated frequency. It is assumed in this example that the array will be deployed with the long axis approximately vertical, so that the measurement 105 represents the spacing in azimuth. Preferably the dimension 105 does not exceed approximately half a wavelength so as to accommodate the design requirements of the components of the module.
By using one or more standard modular elements, manufacturing economies of scale may be achieved for the modules, while permitting many different antenna array arrangements to be assembled for different purposes, thereby providing a flexible and relatively cheap antenna structure.
In preferred embodiments, dielectric material (other than air) may be placed in the open cavity or cavities of the structure. The material may, for example, be placed alongside one, or two opposite, walls of the open cavities. This increases the effective width or height of the cavities as regards the radio frequency (RF) waves resonating in the cavity (e.g. by increasing the electro-magnetic width of the cavities) and thus enables a shorter width or height cavity structure while maintaining the desired resonant frequency for the antenna element. Thus a more compact antenna structure may be achieved. Furthermore, with two-dimensional arrayed antennas required for the purposes of beam forming, as already mentioned, there is a further constraint that the width of each horizontal column of the array should be less than or equal to half the carrier frequency wavelength to enable directed RF beams without grating lobes. Dielectric loading of the cavity of the structure enables the desired resonant frequency to be provided, while meeting the column width constraint for the antennas. This is particularly important for higher frequency (shorter wavelength) bands such as the WiMAX and AWS frequency bands; the spacing between the cover and the enclosure does not scale with frequency, so that this forms a larger proportion of the column width in shorter wavelength systems, leaving a smaller proportion of the width for the cavity.
a, 10b and 10c illustrate alternative arrangements of dielectric material with respect to the antenna structure. In
The beamwidth of an antenna formed with this structure can be modified by placing conducting surfaces immediately alongside the external cover. This is illustrated by
a, 13b, 13c and 13d illustrate the construction of a suitable coupler, for example an overlay coupler.
A coupler such as that illustrated in
In addition, conventional stripline components such as filters could be constructed on one or both of layers 2a and 2b.
It is possible to construct adjustable phase shifters by means of a section of one of the feed layers 2a that can be moved relative to the other feed layer 2b. An example of such an adjustable phase shifter is shown in
An alternative design of a phase shifter is illustrated in
It is also possible to use the region between the enclosure 3 and the cover 1 to accommodate a well-known design of phase shifter, consisting of a sheet of dielectric that can be slid over a track on the feed layer to increase its electrical length. The sheet of dielectric could be inserted between the feed layer 2 and the open end of the enclosure 3 or between the feed layer 2 and the cover 1, or indeed in both positions. The degree of overlap with the track determines the phase shift experienced.
A wide variety of RF stripline structures could in principle be constructed from conductive areas on the feed layers and conveniently accommodated in the region between the enclosure and the cover.
The above embodiments are to be understood as illustrative examples of the invention and other embodiments are envisaged. It is to be understood that any feature described in relation to any one embodiment may be used alone, or in combination with other features described, and may also be used in combination with one or more features of any other of the embodiments, or any combination of any other of the embodiments. Furthermore, equivalents and modifications not described above may also be employed without departing from the scope of the invention, which is defined in the accompanying claims.
Number | Date | Country | Kind |
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0706296.1 | Mar 2007 | GB | national |
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