GB2508898A - Directional antenna array arrangements - Google Patents

Abstract

A directional antenna 1 comprises a first plurality of antenna elements 2 11 forming an antenna array and a second plurality of RF receiver units 13 19 which are fewer in number than that of the first plurality. Each receiver unit 13 19 is arranged to receive RF signals from one or more of the antenna elements 2 - 11 and for outputting a receiver signal accordingly. A signal processor 20 processes the receiver signals 34 according to a directional antenna beam pattern. At least two non-neighbouring antenna elements 2, 5 provide output signals which are coupled to a common RF receiver unit 13 to provide a combined RF signal. The antenna elements 2 11 may each be a sub-array of antenna elements. Also disclosed is a directional antenna comprising a plurality of antenna elements each providing output signals to a respective RF receiver unit where neighbouring RF receiver units are connected to non-neighbouring antenna elements. The output signals from the RF receiver units are provided to a directional beam pattern signal processor.

Description

IMPROVEMENTS IN AND RELATING TO ANTENNAS

FIELD OF THE INVENTION

The invention relates to antenna systems, such as antenna systems comprising multiple separate sub-antennas, or sub-arrays of antennas, used in combination to form an antenna beam such as, but not limited to, phased antenna arrays.

BACKGROUND ART

A phased array antenna system comprises a directive antenna made up of a number of individual antenna radiating elements driven with signals controlled so that the radiation beam pattern produced by the antenna radiating elements collectively may be steered in direction. The converse is true of the receiving beam pattern. The beam of an array of antenna elements can be electronically steered rapidly as a result.

A linear antenna array may consist of antenna elements, or separate sub-arrays of antenna elements, arranged in a straight line in one dimension, typically with an equal spacing between antenna elements, or sub-arrays. An idealised linear array composed of N isotropic array elements with an equal spacing d apart may produce a combined output voltage E in response to an incoming radio signal of wavelength A received from a broadside direction B to the line of the array, which is the sum of the voltages of the voltages of the array elements and takes the form: L sin[r(d/A)sin(9)] This is known as the field-intensity pattern and also corresponds to the radiation beam pattern of the idealised antenna array. It has a maximum values when: sin(8)=±Nr(d/A) The maximum occurring at N=O corresponds to the main beam of the antenna array. The beam of the idealised linear array may be steered in direction to an angle e0 by applying a relative signal phase shift 6 equal to: 3 n2r(d/A)sin(00) between successive elements in the array. The normalised intensity pattern of the linear array then becomes: GW) = rs1nN(d/A)(s1no 0)] 2 vsin[/!Axsin 0-sin 9)] which has a maximum when sin(O) = sin(Oo), thus Oo is the beam direction which may be changed as desired by varying the relative signal phase shift 6. This is an idealised situation, but illustrates the formation of an antenna beam using an array of antenna elements in combination.

So-called "grating lobes", will appear in the intensity pattern of the idealised array at angles eg whenever:

A

sin0 -sin 9 nfl-" Thus, the spacing of the elements (d) should preferably be no greater than half the signal wavelength in order to avoid grating lobes appearing to close to the main beam position. Grating lobes are generally undesirable side lobes within a beam pattern which can cause ambiguities, and can lead to misidentification of objects in radar systems. It is also to be noted that grating lobes may occur not only when the element spacing of an array is too large but also when the regularity of the spacing of the elements (d) is broken. For example, when in an array most of the elements are spaced by a regular distance (d), but some neighbouring elements are spaced by a greater distance (e.g. 2cc, grating lobes appear in the beam pattern. The greater the deviation from regularity in the element array structure, generally speaking, the greater is the size of the resulting grating lobe(s).

The invention addresses this in an antenna structure.

SUMMARY OF THE INVENTION

In a first aspect, the invention may provide a directional antenna comprising: a first plurality of sub-antennas forming an antenna array; a second plurality of RF receiver units fewer in number than the first plurality and each arranged for receiving RF signals from one or more of said sub-antennas and for outputting a receiver signal accordingly; a signal processor for receiving and processing said receiver signals according to a directional antenna beam pattern; wherein at least two non-neighbouring said sub-antennas are connected to a common one said RF receiver unit to provide a combined RF signal thereto.

More than two non-neighbouring said sub-antennas may be connected to a common one said RF receiver unit to provide a combined RF signal thereto and none of the sub-antennas so connected are neighbouring sub-antennas.

Preferably, at least two said RF receiver units are separately connected to a respective at least two non-neighbouring said sub-antennas which provide a combined RF signal thereto.

In a second aspect, the invention may provide a directional antenna comprising: a plurality of sub-antennas forming an antenna array; a plurality of RF receiver units each arranged for receiving RF signals from a respective one of said sub-antennas and for outputting a receiver signal accordingly; a signal processor for receiving and processing said receiver signals according to a directional antenna beam pattern; wherein neighbouring said RF receiver units are connected to non-neighbouring respective said sub-antennas.

The directional antenna may include a signal processor and in which the plurality of sub-antennas form a phased-array of sub-antennas, wherein the signal processor is arrange to control the phases applied to sub-arrays of the antenna array to control the beam pattern direction thereof.

One, some or each of said sub-antennas may comprise a sub-array comprising a plurality antenna radiating elements. A said sub-array preferably comprises a linear array of antenna radiating elements. Each sub-antenna of the antenna array is preferably spaced from each neighbouring sub-antenna by a common distance.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 schematically illustrates an antenna system according to an embodiment of the invention; Figure 2 schematically illustrates an antenna system according to an embodiment of the invention.

DETAILED DESCRIPTION

Figure 1 schematically illustrates an antenna system 1 comprising a vertical stack of ten equally-spaced sub-arrays of antenna elements (2 to 11), each of which is a substantially identical regular horizontally linear array of six radiating elements 12 connected via a common RF signal input/output pod of the sub-array to an RF signal input port of a respective one of seven RF receiver units (13 to 19), and thence to a signal processing unit 20 arranged to process received RF signals and output the result 33 for use as desired.

RF receivers are typically expensive and quite large items of equipment.

Their use in antenna systems, especially in compact and relatively light-weight radar systems, may be minimised as shown schematically in Figure 1.

A first and uppermost sub-array 2 of the ten sub-arrays and a fourth intermediate sub-array 5 of the ten sub-arrays are each connected to the RF signal input port of a common, shared first RF receiver unit 13 via an RF signal transmission line (21, 22) containing a directional coupler 23 for combining the RF signals output by the first and fourth sub-arrays into one combined RF signal for input to the shared RF receiver unit.

The second 3, third 4, sixth 7, eighth 9 and ninth 10 intermediate sub-arrays of the ten sub-arrays are connected, respectively, to a fifth 17, fourth 16, second 14, third 15 and sixth 18 separate, dedicated RF receiver unit via a respective RE signal transmission line (24 to 31).

Einally, the fifth 6 and seventh 8 intermediate sub-arrays and the lowermost tenth sub-array 11 is each connected to the RE signal input port of a common, shared seventh RF receiver unit 19 via an RF signal transmission line (28, 29 and 31) containing a directional coupler 32 for combining the RF signals output by the fifth, seventh and tenth sub-arrays into one combined RE signal for input to the shared RF receiver unit.

Consequently, the first and fourth sub-arrays effectively form one larger "super" sub-array having an effective "super" sub-array centre mid-way between the two sub-arrays which form it. Similarly, the fifth, seventh and tenth sub-arrays effectively form one more even larger "super" sub-array having an effective "super" sub-array centre located between the outer two sub-arrays which form its upper and lower limits.

It is to be noted that the sub-arrays which form a part of any one of the two "super" sub-arrays sharing a common receiver unit are non-neighbouring sub-arrays. The result is that the effective centres of the two "super" sub-arrays is each located substantially close to or between a given two of the other sub-arrays of the antenna array. This means the separation between the effective centre of any "super" sub-array and a given sub-array closest to that effective centre, is not greater than the regular separation between sub-arrays of the antenna array. This minimises the effects of grating lobes for the reasons outlined above in respect of the idealised array example. Had the sub-arrays forming a given "super" all been a succession of neighbouring sub-arrays, the effective mid-point centre of the "super" array would have been spaced from the nearest regular (non-"super") sub-array by a distance exceeding the regular spacing between sub-arrays. This would tend to promote the presence and effects of grating lobes.

The allocation of which of the ten sub-arrays to connect to which of the seven RE receiver units is preferably generated randomly, e.g. via a random selection, with the condition that if more than one sub-array is assigned to a given RF receiver unit, then not all of the sub-arrays are neighbouring arrays, and more preferably that none of the sub-arrays are neighbouring sub-arrays (as shown in Figure 1). This randomised selection/allocation process has been found to provide better suppression of grating lobe effects across the array by spreading out those effects across the array. In other embodiments, only the allocation of the sub-arrays to be connected to a common receiver unit is performed in this way, and the allocation of remaining sub-arrays to single, dedicated receiver units may be non-random. In alternative embodiments the allocation of which of the ten antenna sub-arrays to connect to which of the seven RF receiver units is made to provide optimal antenna performance as desired, subject to the conditions described above.

In any case, the signal processor unit contains a mapping table which tabulates which of the antenna sub-arrays is connected to which of the RF receiver units such that the signal processor 20 may determine the relative is location (within the array) of the sub-array, or "super" sub-array, responsible for a given received signal 34. This is because the relative positions of the receiver units generally no longer correlates directly to the physical positions of the sub-arrays they receive RF signals from in use.

The invention in the aspect illustrated in Figurel, and discussed above, permits a limited number of RF receivers to be used with a greater number of antenna sub-arrays. The benefit is lower cost and weight, while having the advantages of "super" sub-arrays which each have a greater aperture size, gain and resolution than any one sub-array alone, while managing and at least to some extent suppressing the otherwise deleterious effects of grating lobes.

In another aspect of the invention, is illustrated in Figure 2 which shows an antenna system 35 comprising a vertical stack of ten equally-spaced sub-arrays of antenna elements (2 to 11), each of which is a substantially identical regular horizontally linear array of six radiating elements (12) connected via a common RF signal input/output port of the sub-array to an RF signal input port of a respective one of ten RF receiver units (40 to 49), and thence to a signal processing unit 20 arranged to process received RE signals 34 and output the result 33 for use as desired. Each antenna sub-array has a dedicated RF receiver unit connected to it alone, via an RE signal transmission line (50 to 59).

The allocation of which of the ten antenna sub-arrays to connect to which of the ten RE receiver units is preferably made to provide optimal antenna performance as desired, with the condition neighbouring antenna sub-arrays are assigned to a non-neighbouring RF receiver units (as shown in Figure 2).

This selection/allocation process has been found to provide better suppression of grating lobe effects across the array in the event of failure of two or more neighbouring RF receiver units. This is due to the spreading out those effects across the array. The signal processor unit contains a mapping table which tabulates which of the antenna sub-arrays is connected to which of the RE receiver units such that the signal processor may determine the relative location (within the array) of the sub-array responsible for a given received signal. This is because the relative positions of the receiver units generally no longer correlates directly to the physical positions of the sub-arrays they receive RE signals from in use.

Failure of RE signal receivers may often happen due to overheating for example. In such a case, a given overheated receiver unit may cause overheating in a neighbouring receiver unit, typically nearby. Thus, receiver units arranged in an antenna system are susceptible to failure in neighbouring groups. In the even of such a failure, and were it not for the non-neighbour allocation of antenna sub-arrays to neighbouring receiver units, the effect would be the loss of two neighbouring antenna sub-arrays within the antenna array (e.g. the middle two sub-arrays) producing a "hole" in the working antenna array structure. The resultant effect upon the antenna beam pattern would be the generation of grating side lobes for the reasons given above. By avoiding the allocation of neighbouring antenna sub-arrays to neighbouring receiver units, to likelihood of this occurring is minimised because the failure of two neighbouring receiver units does not lead to the loss of a corresponding two neighbouring antenna sub-arrays.

The example shown in Figure 1 and Figure 2 is a vertical array of horizontal antenna sub-arrays with grating lobes suppressed in the elevation direction, however by turning the array through 90 degrees one may provide a horizontal array of vertical antenna sub-arrays with grating lobes suppressed in the azimuth direction.

The embodiments described above are presented for illustrative purposes and it is to be understood that variations, modifications and equivalents thereto such as would be readily apparent to the skilled person are encompassed within the scope of the invention.

Claims (8)

1. CLAIMS: 1. A directional antenna comprising: a first plurality of sub-antennas forming an antenna array; a second plurality of RE receiver units fewer in number than the first plurality and each arranged for receiving RE signals from one or more of said sub-antennas and for outputting a receiver signal accordingly; a signal processor for receiving and processing said receiver signals according to a directional antenna beam pattern; wherein at least two non-neighbouring said sub-antennas are connected to a common one said RE receiver unit to provide a combined RF signal thereto.
2. 2. A directional antenna according to any preceding claim in which more than two non-neighbouring said sub-antennas are connected to a common one said RF receiver unit to provide a combined RF signal thereto and none of the sub-antennas so connected are neighbouring sub-antennas.
3. 3. A directional antenna according to any preceding claim in which at least two said RE receiver units are separately connected to a respective at least two non-neighbouring said sub-antennas which provide a combined RE signal thereto.
4. 4. A directional antenna comprising: a plurality of sub-antennas forming an antenna array; a plurality of RF receiver units each arranged for receiving RF signals from a respective one of said sub-antennas and for outputting a receiver signal accordingly; a signal processor for receiving and processing said receiver signals according to a directional antenna beam pattern; wherein neighbouring said RE receiver units are connected to non-neighbouring respective said sub-antennas.
5. 5. A directional antenna according to any proceeding claim including a signal processor and in which the plurality of sub-antennas form a phased-array of sub-antennas, wherein the signal processor is arrange to control the phases applied to sub-arrays of the antenna array to control the beam pattern direction thereof.
6. 6. A directional antenna according to any preceding claim in which one, some or each of said sub-antennas comprises a sub-array comprising a plurality antenna radiating elements.
7. 7. A directional antenna according to claim 6 in which said sub-array comprises a linear array of antenna radiating elements.
8. 8. A directional antenna according to any preceding claim in which each sub-antenna of the antenna array is spaced from each neighbouring sub-antenna by a common distance.