GB2135131A - Improvements in or relating to monopulse detection systems - Google Patents

Abstract

A planar array (13) of radar antenna elements (B) used in a monopulse detection systems includes means to apply an appropriate phase by the phase delay (4) on transmission and reception so as to define only two beams. Received signals are added to give a sum beam (22), and for a normal beam perpendicular to the plane of the array appropriately weighted, signals are added in phase in a resistor network F1. A signal difference beam (27) is generated by added receiver outputs in a second resistor network F4 with each output phase delay (23) by a phase angle equal to the angular position of the detector measured from the array centre with respect to the array centre line (14). Then a target position can be defined by taking the ratio of the amplitudes and the relative phases of signals received by the sum and difference beams. Beam steering is done by applying additional phase delays to both beams to tilt the phase planes of the array as desired. <IMAGE>

Description

SPECIFICATION Improvements in or relating to monopulse detection systems The invention relates to detector arrays used in active or passive detection systems for producing monopulse tracking.

Conventional monopulse tracking systems require three channels to define the positions of targets within the beam of an array of detectors. Two signal difference channels are required to give information on the target offset in two perpendicular directions and a sum channel gives amplitude information.

Comparison of the magnitude and sign of these difference signals with the sum signals then gives a target's position relative to the centres of the beams.

The object of the present invention is to provide an alternative form of monopulse detection system which requires only two channels to determine the position of targets and is particularly relevant to circular arrays.

The invention provides a monopulse system for detecting energy received from a target comprising: a planar array of detectors responsive to the received energy; a sum channel for adding together outputs from all detectors; a difference channel both for applying to the output of each detector a fixed polar phase delay which is linear in the range (0 - 2 sir), or an integral multiple thereof, in dependence on the angular position of each detector in the plane of the array and for adding together the product signals formed thereby; and means for comparison of the outputs from the two channels to derive the position of the target.The invention thus requires only two channels one of which produces a sum beam and the other a difference beam wherein the relative amplitudes determine the target's angular off-set and the relative phases determine the direction of this off-set as projected on the plane of the array.

The array may be a uniform distribution of detectors as for example by placing detectors at the interstices of a rectangular grid. However in order to reduce the overall system complexity the invention may also be applied to a thinned array wherein selected detectors are omitted from the uniform array.

In the preferred arrangement the array consists of waveguide apertures, dipoles or similar elements for the radiation and reception of r.f. energy. During reception each element may be connected to a receiver which amplifies and/or converts to a lower frequency the energy emitted or reflected by targets.

The separate outputs are then preferably passed through selectable phase delays employed for beam steering. The separate phase delayed outputs are added directly to form the sum beam and are also added after applying the fixed polar phase delays to form the difference beam.

With the selectable phase delays set to zero the sum and difference beams are symmetrical about the normal to the plane of the array with a central peak and a central null respectively. By applying phase delays linearly dependent on the positions of the elements in the array, the phase place may be tilted relative to the plane of the array, thereby steering the beams.

Circuitry may be included in the system to automatically steer the sum and difference beams to maintain a target on the axis of the sum beam.

Side lobes in the radiation patterns of both the sum and the difference beams may be attenuated by carrying out the addition of the respective signals in the two channels in weighting circuits, wherein each detector output is weighted as a function of the distance of the detector from the centre of the array.

The fixed polar 0 - 21r phase delays applied to the receiver outputs in the difference channel may be introduced by appropriate lengths of transmission line connecting the receivers to the difference channel addition circuit.

In order that these features may be more fully appreciated the invention will now be described by way of example only with reference to the accompanying drawings of which: Figure lisa schematic arrangement to illustrate a monopulse radar tracking antenna; Figure 2 is a functional circuit diagram of a monopulse tracking radar; Figure 3 is a circuit diagram of signal processing circuits in a conventional monopulse radar; Figure 4 is a circuit diagram of signal processing circuits according to the invention for producing a polar coordinate monopulse radar; Figure 5 is a geometrical representation of the planar array used to define the polar coordinate monopulse radar; and Figure 6 illustrates the radiation patterns (response curves) of the two beams of the polar monopulse radar.

Monopulse systems started with the use of four horn aerials in a square formation feeding a reflector. A typical arrangement is shown in Figure 1 wherein the four rectangular horns A,B,C and D are placed on the axis of a reflector R. The respective signals received from the horns A to D may be respectively added and subtracted to give a sum signal Sand two difference signals Ax and Ay as follows: S=A+Bt-C+D Ax = (A + D)(B + C) Ay = (A + B) - (C + D) By comparing the magnitude and sign of the difference signals Ax and Ay with the sum signal S an azimuth and an elevation servo motor connected to the aerial system can be driven in the appropriate directions to reduce the difference signals to zero and so keep track of a target.

This system of separate Ax and Ay signal channels has been adopted in conventional aerial arrays employing phase shifters and feeder networks to a centralised transmitter and receiver to isolate the sum and the two difference signals. Since the feeder networks are normally disposed horizontally and vertically the provision of separate rectangular coordinate Ax and Ay difference signal channels is a logical arrangement. However this is no longer necessary in an electronically scanned active array in which each element or small group of elements within the array is associated with a separate receiver. It is then possible to provide phase shifts by IF or digital processing. This type of processing makes possible two or more outputs of any desired phase from each receiver without reducing the signal to noise ratio.

Figure 2 shows a planar antenna array A, circular or near-circular in shape, which is fully or partially filled with antenna elements B. Each of the elements B is connected by a transmitter 1 or receiver 2 according to whether the associated switches Si, S2 and S3 are respectively in the lower position (as shown) or the upper position.

During transmission, power from the transmitter 1 is fed via a divider 3 to all the radiating antenna elements B via respective phase shifters 4. The output from each phase shifter 4 may be fed via an optional amplifier 5 to the antenna element B.

During reception, the divider 3 is used to feed power for a local oscillator 6 via the respective phase shifters 4 and inputs 7 to rf mixers in the receivers 2.

Signals received in the antenna elements B are fed to inputs 8 in the respective receivers 2 where they are down-converted to an IF frequency signal at the receiver output 9. For both transmission and reception the direction of maximum gain - the main beam - is controlled by the settings of the phase shifters 4.

In the conventional system the output signal from each receiver 2 is processed as shown in Figure 3 to provide three IF outputs 10,11 and 12. Forth sum signal output 11 (equivalent to S) all the receiver outputs 9 have equal path lengths to the resistor network F, where they are summed. In most cases signals received by antenna elements 13 towards the edge of array A have additional resistive attenuation 14 (say) in order to suppress side-lobes in the antenna sensitivity pattern. For the azimuth signal output 10 (equivalent to Ax) the signals from all the antenna elements to the left of the centre line 14 of the array A are summed in anti-phase to those on the right in the network F2.Thus the signal from each receiver output 9 is fed to the network F2 via a phase delay 15 set to 0 or radians depending upon whether the associated antenna element B is respec tively to the left or right of the array centre line 14.

Similarly for the elevation signal output 12 (equivalent to Ay) signals from antenna elements above the array centre line 16 are summed in antiphaseto those below in the network F3. Signals from each receiver output 9 are fed via a phase delay 17 to the network F3 with the phase delay set to 0 or tor radiants depending upon whether the associated antenna elements are respectively above or below the line 16.

In both of these difference outputs 10 and 12 low side-lobes are achieved by attenuating or weighting the individual signal amplitudes by an appropriate choice of resistor 17 or 18 depending on the distances of the individual elements from the respective centre lines 14 and 16 as well as from the centre of the array.

The signals in the three IF outputs 10 - 12 can then be processed in three identical channels. Finally after separation in known manner by range gates the phase and amplitude of the signals in the difference channels are compared with phase and amplitude of the signal in the sum channel to determine the angular offset of targets in the horizontal and vertical directions.

According to the present invention the circuit arrangement shown in Figure 4 is used in cooperation with the antenna array A and circuitry shown in Figure 2. The invention replaces the conventional rectangular cartesian co-ordinate system by applying polar coordinate dependent phases to produce a polar monopulse radar system.

As before the outputs from the receivers 2 associated with each antenna element B in the array A are summed in a weighting network F, of resistors 19 21 (of which only three are shown) to produce a conventional sum signal (Z) at the output 22 from the network F1. The output 9 from each receiver 2, however, is also applied via a fixed polar phase delay 23 and to a second weighting network F4 of resistors 24 -26 to produce a signal weighted output difference signal 27 (A). The fixed polar phase delay 23 introduces a phase shift for each antenna element B equal to the angle H of the element measured in a clockwise sense from the array centre line 14. This is achieved by using appropriate lengths of cable to connect the receivers 2 to the network F4.The polar monopulse thus requires only two channels with two weighting networks F1 and F4 compared with the three networks required in the conventional Figure 3 arrangement. In addition, amplitude weighting in the F4 network of the difference channel depends only on the distance of the antenna element from the centre of the array ie there is circular symmetry for this channel as well as for the sum channel.The sum output 22 (E) and the difference output 27 (A) are then combined to determine the angular position of the target uniquely by taking the amplitude ratio A/E to give the angular offset of the target from the boresight direction, and the phase difference, Xs XD, between the two outputs to give the radial direction of the target relative to the centre line 14.

In a circular array of detectors a phase mode can be selected such that the phase of the individual elements varies linearly with their angular position, with a total phase of 21run = 3600, where n is an integer. It is then possible by suitabiy phased addition of the various modes to generate a beam or a null in particular directions in the plane of the array. This consideration is extended to a circular planar array in the present invention by considering what happens in planes normal to the array. Figure 5 indicates a typical antenna element 28 in a planar array located at an angle Ofrom the array centre line 29 and a distance rfrom the centre 30 of the array.

The amplitude of excitation of the array is a function of the radial distance r only and is represented by: Amplitude = f(r) If n - o, there is a constant phase over the face of the array and a beam is formed normal to it. For the sum (X) pattern n is chosen to be zero. The cross-section of the resulting beam is indicated by the pattern 31 in Figure 6 as a symmetrical beam centred on the boresight 32 (normal to the plane of the array, through the array centre 30). For the polar difference (A) beam n is chosen to be one. In this case the amplitude excitation of the array as shown by the pattern 33 is symmetrical with a null 34 in the bore sight direction 32 surrounded by an annular peak 35, constant in amplitude, but with a 360 change of phase around it.

Thus, if a target is within the sum (Z) beam 31 the ratio of the amplitudes of the signal returns in the sum 31 and polar difference 33 beams indicates the angular distance of the target off boresight. Com parison of the phases of the two returns (+s: : then indicates the radial direction of the target. It is also possible to choose integer values of n greater than 1. This gives higher angular resolution at the expense of ambiguity.

Although not shown in Figure 6 for the purpose of simplicity a uniform amplitude distribution in a difference pattern generally leads to high side-lobes as well as a lower monopulse angular sensitivity. In the usual rectangular coordinate monopulse systems lower side-lobes and greater angular sensitivity are obtained by applying a linear taper in amplitude proportional to the distance of the antenna element from the centre of the array. This is also true for the polar coordinate monopulse system. It can be shown that this tapering results in a difference radiation pattern of circular symmetry with a cross-section identical to that of the conventional difference pattern, though with a doubling of receiver noise.The side-lobes can be further lowered by reducing the amplitude close to the edge of the array, but in this case the polar monopulse does not correspond exactly with the conventional difference pattern.

With a uniform phase across the array as described above the sum beam is aligned on the boresight ie along the array axis perpendicular to the plane of the array. In order to steer the beams to some other direction a uniform phase slope has to be applied across the face of the array. The uniform phase slope is applied in known manner by setting the phase delays in the phase shifters 4 so as to be linearly dependent on the positions of the respective detectors in the array. In the case of the polar difference beam the same phase slope must be added to the phase mode.

The annular peak of the difference beam will remain undistorted in terms of sin a (where a is the angle from boresight, however in terms of a it will appear somewhat egg-shaped. It may therefore be preferable to perform the calculation of the position of a target offset from the null in terms of sin CL space and then convert to actual angles. In general the phase shifts applied to the individual antenna elements will also be quantised (as for the conventional monopulse) and this quantisation introduces an angular error. The angular error will be increased by reducing the number of antenna elements as in conventional thinned arrays.It can be shown that the angular accuracy of the polar monopulse is independent of direction, and equal to that which the conventional monopulse achieves in direction at 45O to the centre line axis 14 of array.

The polar difference beam of the present invention is more difficult to set up than the conventional monopulse since it involves radial amplitude and circumferential phase changes across the face of the array. By comparison each conventional monopulse difference beam involves amplitude changes in two dimensions but with a single phase reversal at the central axis.

The polar monopulse however requires only two channels instead of three for tracking. This gives a saving of one third in the cost of signal processing and in such auxiliaries as jamming cancellation loops. Apart from the example described above the invention is applicable to any detection system in which both the phase and amplitude of the individual elements is preserved. The combining networks can be at rf, if, or If or alternatively digital signals including phase information can be combined in a computer. In a further modification the outputs from small groups or sub-arrays of antenna elements can be combined as for the individual antenna elements, described. Further modifications within the scope of the invention described will be apparent to those skilled in the art.

Claims (8)

1. A monopulse system for detecting energy received from a target comprising: a planar array of detectors responsive to the received energy; a sum channel for adding together outputs from all detectors; a difference channel both for applying to the output of each detector a fixed polar phase delay which is linear in the range (0 - 2err), of an integral multiple thereof, in dependence on the angular position of each detector in the plane of the array and for adding together the product signals formed thereby; and means for comparison of the outputs from the two channels to derive the position of the target.

2. A monopulse detection system as claimed in claim 1 wherein the array consists of waveguide apertures, dipoles or similar elements for the radiation and reception of r.f. energy.

3. A monopulse detection system as claimed in claim 2 wherein during reception each element may be connected to a receiver which amplifies and/or converts to a lower frequency the energy emitted or reflected by targets.

4. A monopulse detection system as claimed in any one preceding claim wherein the output from each detector element is also connected to a selectable phase delay employed for beam steering, the outputs from the selectable phase delays being added directly to form the sum beam and being also added after applying the fixed polar phase delays to form the difference beam.

5. A monopulse detection system as claimed in claim 4 further including circuitry to automatically steer the sum and difference beams to maintain a target on the axis of the sum beam.

6. A monopulse detection system as claimed in any one preceding claim wherein side lobes in the radiation patterns of both the sum and the difference beams are attenuated by carrying out the addition of the respective signals in the two channels in weighting circuits, wherein each detector putput is weighted as a function of the distance of the detector from the centre of the array.

7. A monopulse detection system as claimed in any one preceding claim wherein the fixed polar 0 2sr phase delays applied to the receiver outputs in the difference channel are introduced by connecting appropriate lengths of transmission line between the receivers and the difference channel addition circuit.

8. A monopulse detection system substantially as described with reference to Figures 1, 2 and 4 - 6 of the accompanying Drawing.