SYSTEM AND METHOD FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR

Abstract

A SYSTEM FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR, comprising a plurality of N antennae with a narrow beam in elevation and wide in azimuth, regularly disposed on a rotary base coupled to an engine, the elevation orientations of said antennae being staggered according to a defined pattern, each antenna being associated to a radar device endowed with computer means furnishing information relating to distance, azimuth, elevation and speed of fixed and moving obstacles above and below the plane of said rotary base. Some antennae point towards a place above the horizon, the angles of view being progressively descending so as to cover a volume that extends above and below the plane of the horizon, and may reach the ground. Said volume results from the sum of the volumes of superimposed cones, each cone corresponding to an elevation angle. The system combines the images of the N conical volumes to provide the pilot or operator a three-dimensional image.

Claims

1. A SYSTEM FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR, wherein comprising a plurality of antennae, regularly disposed on a rotary base coupled to an engine, the elevation orientations of said antennae being staggered according to a defined pattern, each antenna being associated to a radar device endowed with computer means furnishing information relating to distance, azimuth, elevation and speed of fixed and moving obstacles above and below the plane of said rotary base, covering an angle of 360 degrees in azimuth.

2. THE SYSTEM FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR as claimed in claim 1, wherein said staggering consists of uniform and sequential variations of the elevation angle of said antennae.

3. THE SYSTEM FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR as claimed in claim 1, wherein comprising N antennae, the first of them having an elevation angle above the plane of said rotary base, and the following having elevation angles progressively descending, finalizing with angles below said plane.

4. THE SYSTEM FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR as claimed in claim 1, wherein said computer means use the ROSAR technique to determine the resolution in azimuth of each target.

5. THE SYSTEM FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR as claimed in claim 1, wherein said computer means use Doppler processing to determine the speed of each target.

6. THE SYSTEM FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR as claimed in claim 1, wherein said rotary base is coupled to the aircraft by means of a Cardan joint.

7. THE SYSTEM FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR as claimed in claims 1, wherein said antennae are provided by slotted waveguides.

8. THE SYSTEM FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR as claimed in claim 1, wherein said antennae are provided by planar antennae.

9. A METHOD FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR, wherein simultaneously scanning N conical regions superimposed by radars and forming a three-dimensional image by the geometric combination of the N images obtained.

10. THE METHOD FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR, as claimed in claim 9, wherein each said conical region corresponds to a different elevation angle of an antenna associated to each of said radars.

11. THE METHOD FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR, as claimed in claim 9, wherein said elevation angles vary by uniform steps between an initial angle above the horizon and a final angle below the horizon.

12. THE METHOD FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR, as claimed in claim 9, wherein said antennae cover circular paths of 360 degrees, at a constant speed between 150 rpm and 900 rpm.

13. THE METHOD FOR DETECTING AND VISUALIZING TARGETS BY AIRBORNE RADAR, as claimed in claim 12, wherein said circular paths have a diameter between 30 cm and 3 meters.

Description

DESCRIPTION OF THE DRAWINGS

[0013] The other advantages and characteristics of the invention will be better understood by the description of a preferred embodiment and the drawings referring thereto, wherein:

[0014] FIG. 1 is a perspective view of the proposed system.

[0015] FIG. 2 is a simplified view of the system installed on a helicopter.

[0016] FIG. 3 shows the region of the space monitored by the system of the invention.

[0017] FIG. 4 is a block diagram of the system of the invention.

[0018] FIG. 5 refers to detecting various obstacles with the aircraft in movement.

DETAILED DESCRIPTION OF THE INVENTION

[0019] The Synthetic Aperture Radar (SAR) systems originally described by Klausing and Keydel in U.S. Pat. No. 5,017,922 entitled Radar System Having a Synthetic Aperture on the Basis of Rotating Antennae), airborne or orbital, has evolved significantly with the combination of the use of various frequencies or bands, X, L, P and the polarization (indicates the direction of the electric field of the wave transmitted or received), Vertical (V) or Horizontal (H) of the signals emitted and received, with equal or inverted polarization (VV, HH or VH), obtaining high definition images, in color and 3D. The combinations of the techniques used are dictated by the objective to be achieved, comprising maps, level curves, surface model, treetop height and others, particularly flight control systems for pilots of aircraft.

[0020] As can be inferred from FIG. 1, the present invention comprises a plurality of antennae 15, 16, 17, . . . 30, consisting of slotted waveguides, regularly disposed on a circular base 11 with axis of rotation 12 driven by an engine 31 which is fastened by way of a flange 37 to the fuselage 40 of an aircraft, as illustrated in FIG. 2. This figure also shows that said circular base and said antennae are outside the fuselage, being protected by a radome 41. This arrangement allows the fuselage to be made of metal, potentially bulletproof, as required by aircrafts destined for combat.

[0021] Further according to FIG. 1, it is noted that the antennae do not point in the same elevation, being directed at rising angles, 3 by 3 starting from antenna 15 which points to an angle of 15 above the plane of the base 11. Thus, the last antenna of this set points to an angle of 30 below this plane, which is more clearly illustrated in FIG. 2, in the present exemplary embodiment.

[0022] Each antenna corresponds to a radar, thus consisting of an exemplary embodiment in discussion of 16 radars, each one scanning a swath whose coverage is a cone with a height of 3, as schematized in FIG. 3. The set of these cones forms a cylinder which extends from the first upper swath 1 to the last lower swath, which partially or totally covers the land 42, as illustrated in FIG. 2.

[0023] The axis 12 is tubular to enable the passage of the electric wiring, and the information provided by the system and its forwarding to the other on-board equipment, by sliding contacts 13-13 and 14-14.

[0024] According to FIG. 1, the antennae are connected to the blocks 32, 33, 34 and 35 which house the analog front-end circuits of the radar signals, which after being digitalized are sent to the central block 36 for further treatment and forwarding to said sliding contacts.

[0025] For a more detailed exposition of the invention, we shall now draw reference to FIGS. 3, 4 and 5. As shown in the first of these figures, the aircraft is located at A, coinciding with the axis of the cylinder with radius R and with horizon line H.

[0026] The visualization method for aircraft navigation and landing is based on the use of N radars (in the present case, N=16), each provided with an antenna pointed to elevation angle e. Radar 1 has a positive elevation angle 1. Radar 2 has the beam pointed to an elevation angle 2, 3 less than the prior one and so on and so forth, and radar 4 (not illustrated in FIG. 3) points towards horizon H, that is, with 4 equal to zero. Radars 5 to N present negative elevation angles. Radar N present the most negative elevation angle. The beams with positive Be are for detecting obstacles above the aircraft, such as high voltage power lines. Those with e near zero for detecting obstacles in front of the aircraft. Those with e below zero for detecting obstacles beneath the aircraft and also on the ground. The last beams are dedicated for imaging the ground.

[0027] FIG. 5 exemplifies the operation of the system in the presence of 3 targets: T1a, T1s and T2. T2 has a range R2 and is only seen by radar 2, since the other radars have elevation angles that do not illuminate T2. In this case, the radar operator knows that the target T2 is above the horizon.

[0028] The targets T1a and T1s are only seen by the beam N1. Thus the operator knows that they are near the ground. From the known angles 2 and n1 and from the range, the operator knows exactly the position of the 3 targets in relation to the aircraft.

[0029] The height of the aircraft in relation to the ground is also extracted automatically. The last beams such as N and N1 present the range of the last target, which is the ground.

[0030] This is the major advantage of the system of the invention: the operator has a safe and comprehensive vision of all the targets near the aircraft on a cylinder which begins above the aircraft and extends as far as the ground.

[0031] Additionally, the system provides the speed measurement of the target, since it has Doppler processing. If the target is moving, the radar will provide its radial speed. The target may be a car or the projectile of a firearm or a missile.

[0032] Through ROSAR processing, each of the N radars has a very high resolution in azimuth, general below 0.5 degrees. In this case, the target T2 is located to the right of the aircraft and the targets T1a and T1s to the left of the aircraft, the displacement of which is symbolized by the arrow 43.

[0033] The resolution in azimuth of each of the radars is approximately:

azimuth=/(2*D),

wherein is the wavelength and D is the rotation diameter of the radar antenna according to the ROSAR principle.

[0034] The resolution in range is given by:

R range=2*C/B,

wherein C is the speed of light and B the bandwidth of the transmission pulse, and also the bandwidth of the system.

[0035] The resolution of each beam of the radar in elevation, that is, the value of elevation is given by:

elevation=/L,

wherein L is the vertical length of the radar antenna.

[0036] Based on the preceding description, the target T2 is represented here by a high voltage power line, is to the right and above the aircraft. Targets T1a and T1s to the left and below the aircraft. Target T1a is represented by a tree, stationary target, posing a threat of collision with the aircraft. Target T1s is on the ground, but in movement at radial speed V. Since the N radars are Dippler radars, they can measure the radial speed of the target directly.

[0037] As an example of requirements of this system for helicopters, a range radius of 3 km is considered, the most positive e is 15 degrees and the most negative is 35 degrees.

[0038] The rotation diameter of the antennae is between 0.3 m and 3 m, preferably from 1 to 2 meters, providing an angular resolution in azimuth of tenths of a degree. The resolution in range is 1 m being achieved with a pulse and band width of the system of 200 MHz. The resolution in elevation is 3 degrees, being achieved by an antenna with a length of 17 cm using a frequency of 35 GHz.

[0039] FIG. 4 presents a block diagram of the system. The N antennae, with different N angle elevations are connected to their respective radio frequency systems, 133-1 to 133-N, where the frequency converters are found, along with the transmission channel with power amplifier and the reception channel with a low noise amplifier at the input.

[0040] Thereafter, all the analog outputs and inputs of the RF systems, 133-1 to 133-N, are connected to the processing system 134. It consists of N processers and signal generators, 141-1 to 141-N, which generate the transmission pulse, digitalize the reception signal, make the processing in the range direction to obtain a high resolution in range, make the ROSAR processing to obtain a high resolution in azimuth and make the Doppler processing to determine the speed of each target.

[0041] The 3D imaging subsystem and indication of the moving targets, 142, geometrically joins the N images or slices of the N radars, each scanning a different elevation angle, and forms a three-dimensional image for the operator. Additionally, it adds the speed of moving targets graphically. For geometric correction of the three-dimensional image, the information on position and orientation of the aircraft are used.

[0042] The orientation sensor, 143, located on the fixing platform of the antennae, provides the roll, pitch and heading angles of the N antennae 15 to 30 (see FIG. 1), due to the fact that the rotary system may be coupled to the aircraft by way of a Cardan axis.

[0043] The three-dimensional image generated by 134 is sent to the monitor of the pilot or operator 135 and also to other navigation support systems of the aircraft 136.

[0044] For the three-dimensional image to have frequent updates and the system to accompany the movements of the aircraft, the rotation of the antennae for generating the synthetic aperture ROSAR must be in the magnitude of hundreds of rotations per minute such as, for example, varying between 150 and 900 rpm. In the example under discussion, a rotation of 600 rpm is adopted.

[0045] Although the invention was described based on a specific exemplary embodiment, it is understood that modifications may be made by persons skilled in the art, provided that they are kept within the ambit of the invention.

[0046] So, for example, the irradiating elements 15, 16, . . . , 30 which, in the present exemplary embodiment, are provided by slotted waveguides, may be replaced by antennae based on other technologies, such as planar technology, provided they have similar radiation direction characteristics.

[0047] Accordingly, the invention is defined and limited by the accompanying set of claims.