DESCRIPTION

TITLE: Long Range Object Detection System

Technical area :

The present invention is in the field of object detection systems, or radars. It relates in particular to detection systems used for three-dimensional (3D) localization.

Previous technique:

[0002] The armed forces deployed in theaters of operations are confronted with increasingly diversified short-range threats (rockets, mortars, missiles, drones, small planes, vehicles, infantry, etc.). The surveillance means currently available are generally suitable for detecting and locating a particular type of threat, particularly in terms of detection distance capacity.

[0003] When the threats are diverse, it is often necessary to deploy

several types of heterogeneous systems in parallel to process them, which multiplies the logistical and human footprint during implementation.

[0004] These systems are often short-range radars (with two or three

dimensions) whose aerial is a few meters above the ground. To date, there is no single radar solution taking into account the diversity of threats.

[0005] If the threats evolve over time, for example, by being smaller and smaller (reduced SER) or by having to be detected further away (increase in range) to improve the detection warning, it is then necessary to evolve/change the systems in place.

[0006] There are few solutions for improving the range performance of a radar. They consist of:

- or increase the transmission power and the size of the radar antenna. These solutions quickly lead to complex systems that have a direct impact on the cost of the equipment and its logistical footprint. For example, doubling the antenna surface or the transmission power (+3dB) only saves 20% on the range of the radar system against a reference target, the range of a radar evolving according to the distance with a law in d4, with d the distance;

- either increase the radar visibility, by installing the radar:

o on a high point, such as a geographical point, but such a point is not necessarily available,

o at the top of a high mast or pylon, however, the weight of the radar system imposes significant constraints on the structure of such a mast, its deployment and its maximum height, o under an airborne device such as than a balloon filled with a light gas

like helium. In this case, the dimensioning of the balloon is directly linked to the payload to be carried. For example, a load of 35kg requires a ball a few meters long, while a load of 200kg requires a large ball (greater than 25 meters). The implementation is therefore complex when the mass of the radar is greater than a few hundred kilograms, a large balloon presenting significant acquisition and deployment costs. In addition, the energy consumption and the cooling of these devices require high-section power lines, the weight of which can lead to exceeding the admissible load. The same applies when the airborne device is of a different nature, such as a drone for example.

[0007] An object of the invention is therefore to propose a detection device having an extended range on rockets, or other type of missiles, but also a simultaneous capacity for detection and 3D localization on aerial threats such as drones. , helicopters and microlights, and/or vehicles and/or humans on the move, while ensuring that the cost of the device, its weight, its complexity of implementation and its complexity of deployment are lower than for known solutions .

Figure 1 shows very briefly the various components of a detection device. This comprises a radar processing device 101, in charge on the one hand of generating or playing a radar signal, and on the other hand of receiving one or more echo signals, and of implementing signal processing algorithms to locate objects in a two-dimensional (2D) or three-dimensional (3D) environment.

[0009] The radar processing device is connected to a transmission device 102

configured to receive from the radar processing device a signal to be transmitted, and to transmit it according to a given configuration, comprising a transmission power, transmission times, a transmission frequency and/or a transmission direction. The transmission device 102 therefore comprises a digital-to-analog converter (DAC) in order to convert the signals which are transmitted to it by the radar processing device when these are digital, a radiofrequency chain for amplification and transposition of the signal on carrier frequency when it is st received in baseband or on an intermediate frequency, as well as one or more transmitting antennas, such as for example an omnidirectional antenna such as a dipole or a directional antenna such as a patch antenna or an array antenna .

[0010] The radar processing device 101 receives signals from a signal reception device 103. The latter is configured to receive signals in echo of the signals emitted on one or more sensors. Each sensor comprises at least one radiating element, omnidirectional in a plane or directional depending on the configuration. These sensors can be networked to form a directional antenna. The signal reception device 103 is configured to acquire the signals received from one or more sensors according to given configuration parameters, such as reception times, reception frequency and/or reception direction, and to transmit them to the radar processing device for analysis purposes. Each sensor is connected to a radiofrequency chain configured to filter and amplify the received signal, and to transpose it to baseband or frequency

intermediary when necessary. If the signal transmitted to the radar processing device is a digital signal, each sensor is also connected to an analog to digital signal converter (ADC). Alternatively, the radio frequency chain and/or the analog to digital converter can be integrated into the sensor.

[0011] The various elements of the detection system can be co-located or grouped together in a single piece of equipment: this is called monostatic radar. They can also be split into several distinct pieces of equipment: we then speak of bistatic radar when transmission and reception are separated. Co-located radars generally use the same antennas to transmit and receive signals, in order to reduce the size, weight and cost of the equipment.

[0012] The radar processing device 101 is a calculation device,

digital preference, generally in the form of software embedded on a component such as a processor, a digital signal processor (better known by the acronym of DSP for "Digital Signal

Processor”), or a specialized circuit such as an ASIC (English acronym for “Application Specifies Integrated Circuit”) or an FPGA (English acronym for “Field-Programmable Gate Array”).

[0013] From the signals transmitted by the transmitting device and the signals received from the receiving device, the radar processing device detects and tracks targets present in the space to be monitored. These are characterized by a distance, an azimuth and an elevation, and possibly by other parameters such as their Doppler speed. For this, many methods are known from the state of the art. Among them are phase or amplitude interferometry processing, such as Adcock gratings, beam forming techniques, or so-called high-resolution processing, such as the MUSIC algorithm (acronym for Multiple Signal Classification).

[0014] These different methods impose particular constraints on the

number of radiating elements of the transmitting 102 and receiving 103 antennas, and on their arrangements: for example, an Adcock array requires several antennas spaced apart by a difference proportional to the wavelength of the signals, an array antenna comprises a plurality of radiating elements spaced apart by a distance proportional to the wavelength. The sizing of radar systems is therefore closely linked to the frequency of the signals used. In particular, low frequency radars require large and widely spaced transmit and receive antennas, while high frequency radars are more compact.

[0015] In addition, detection in three dimensions requires the implementation of a mechanically movable directional antenna along two axes or radiating elements distributed in two perpendicular planes.

Summary of the invention:

[0016] In order to respond to the problems of the prior art, the invention describes a

system for detecting the presence of objects and estimating their direction and distance according to three dimensions comprising:

- an emission device configured to emit signals according to a colored emission process in a foreground,

- a reception device comprising at least two sensors arranged in a second plane perpendicular to the first plane, and

- Processing means (230, 330) of the transmitted and received signals.

[0017] The processing means are configured to detect the presence of objects and estimate their direction and distance:

- in the foreground from the signals received from at least one of the sensors of the receiving device in use ant the coloring of the emitted signal,

- in the second plane from the signals received from at least two of the sensors of the receiving device.

The transmitting device and the receiving device are separated, the receiving device being raised relative to the transmitting device.

Advantageously, and so as to allow detection over the entire foreground, each sensor comprises an omnidirectional radiating element in the foreground.

According to one embodiment, the first plane is a horizontal plane, in which the sensors of the reception device are arranged in a vertical plane. Advantageously, the sensors of the reception device are then connected by a cable and suspended under an airborne device allowing them to be raised, such as an inflatable balloon or a drone. Advantageously, a single sensor is used

to detect the presence of objects and estimate their direction and distance in the foreground, preferably the highest sensor.

[0021] According to another embodiment, the first plane is a vertical plane and the sensors of the receiving device are arranged in a horizontal plane.

[0022] The sensors of the receiving device can then be arranged in line, the system also having means for eliminating ambiguities in the position of the objects with respect to the sensors in the horizontal plane.

[0023] The sensors of the receiving device can also be arranged so as to form a triangle, the detection of the presence of objects and the estimation of their direction and distance in the horizontal plane being carried out for each branch of the triangle respectively, then combined in such a way as to eliminate ambiguity on the position of the objects relative to the sensors in the horizontal plane.

[0024] Advantageously, the sensors of the reception device are connected to the

processing means via an optical fiber link, the sensors further comprising means for converting the received signals to optical signals. The use of an optical fiber link makes it possible to reduce the mass of the cable used to transmit the signals acquired by the sensors of the reception equipment, and therefore the mass of all the reception equipment.

[0025] The detection of the presence of objects and the estimation of their direction and

distance in the second plane can be achieved by implementing an interferometry process or high resolution processing on the signals received from the at least two sensors of the reception antenna. Alternatively, it can be implemented by exploiting the directivity of an array antenna formed by the at least two sensors of the receiving antenna.

The invention also describes a method for implementing detection of the presence of objects and estimation of their direction and distance in three dimensions in a detection system comprising:

an emission device configured to emit signals according to a color emission method in a first plane,

a reception device comprising at least two sensors arranged in a second plane perpendicular to the first plane, and

means for processing the transmitted and received signals.

The method comprises the steps of:

- emission of a signal according to a colored emission process in a foreground,

- reception of signals from at least two sensors arranged in a second plane perpendicular to the first plane, and

- implementation of a method for determining the presence of objects and estimating their direction and distance in the first plane by exploiting the coloring properties of the signal received by at least one of the sensors, and in the second plane at from signals received from at least two of the sensors.

Brief description of figures:

The invention will be better understood and other characteristics and advantages will appear better on reading the following description, given without limitation, and thanks to the appended figures, including:

- Figure 1 shows a system for detecting the presence of objects and estimating their direction and distance, or radar, as known from the state of the art;

- Figure 2 shows a first embodiment of a system of

detecting the presence of objects and estimating their direction and distance according to the invention;

- Figure 3 shows a second embodiment of a system of

detecting the presence of objects and estimating their direction and distance according to the invention;

- Figure 4 shows a third embodiment of a system of

detecting the presence of objects and estimating their direction and distance according to the invention;

- figure 5a represents the losses linked to the interference fringes, for equipment located at ground level;

- figure 5b represents the losses linked to the interference fringes,for equipment located 50 meters above the ground;

- Figure 6 shows the steps of an embodiment of a method for implementing three-dimensional object detection according to the invention

Subsequently, when the same references are used in different figures, they designate the same elements.

Detailed description :

In order to respond to the problems posed by the devices of the prior art, the invention observes that the transmitting device has a much greater weight than the receiving device. This is due in particular to the mandatory presence of high-power amplifiers, power electronics elements such as high-capacity capacitors, elements necessary to ensure cooling of the amplifiers, as well as power lines.

high-section power supplies required to power the assembly. The invention proposes to separate the transmission part from the reception part, like a bistatic radar, and to raise the reception device as a priority. In this way, the mass of the load to be raised is reduced in significant proportions, which simplifies the implementation of the system, and makes it possible to improve the propagation conditions for the reception part at a lower cost. In addition, raising the receiving antenna significantly limits interference fringes and losses for targets at low altitude.

[0031] To allow the three-dimensional localization of objects while reducing the complexity of implementation, the invention proposes to rely on a method of colored emission of signals, also known as simultaneous multiple emission. . This process, cited for example in the article "Colored emission for active radar antenna", François Le Chevalier, Laurent Savy, REE N°03, Revue de l'Electricité et de /'Électronique, March 2005, pages 48-52, consists of dividing the space in which the transmit antenna emits into sub-networks using MIMO (acronym for "Multiple Input Multiple

Output”) or MISO (English acronym for “Multiple Input Single Output”). By shaping the signal transmitted from the different radiating elements of the transmit antenna, different signals are sent to each of the sub-networks, thus performing a spatio-temporal coding of space. The signals then combine in space according to phase shifts or delays that depend on the target direction. This results in an overall signal that differs from direction to direction. On reception, to detect a signal coming from a given direction, the processing performs a filtering adapted to the signal associated with this direction. This filter is not suitable for signals from other directions since the signal is no longer the same in these other directions.

[0032] European patent application EP 2 296 007 A1 describes a beam agility radar in which detection is carried out in a plane from the coloring of the signals, and in the orthogonal plane by forming beams.

[0033] Figure 2 shows a first embodiment of a system of

detection of the presence of objects and estimation of their direction and distance in 3D according to the invention. Obviously to those skilled in the art, the detection system according to the invention also makes it possible to detect other

characteristics of the objects, such as for example their speed. In this embodiment, the transmission device 201 is placed at the top of a telescopic mast self-supported by a vehicle, but it could also be directly installed on the ground. The height h1 of the telescopic mast is constrained by the heavy weight of the emission device.

[0034] The transmission device is configured in such a way as to transmit a transmission signal

colored manner in the horizontal plane. This can be achieved from a directional antenna emitting a colored signal whose direction and color vary over time, or from an array antenna comprising several radiating elements each emitting a signal. The emissions can be directive or omnidirectional, in the horizontal plane and/or in the vertical plane. The transmission device is connected to a radar processing device 230, which in the example is on board the carrier vehicle, but whose arrangement is of little importance.

The reception device comprises several sensors 21 1 to 215 separated from the transmission device, arranged in line and vertically, thus forming together a reception network antenna. The sensors are connected by a cable to a high point such as an inflatable balloon 221 or to any other element making it possible to suspend the reception device (drone, crane, pylon, etc.), so that they are placed between the ground and the high point. The sensors of the reception device are also connected to a radar processing device 230 by a cable 220 which transports the signals and the power supplies.

This cable can be the same as that ensuring the maintenance of the sensors, and/or that ensuring the maintenance in position of the balloon 221. The solution in which the cable used for the transmission of the signals is different from the cable maintaining the balloon 221 is however preferable. to facilitate the deployment and folding of the device. Due to the low weight of the sensors, the height h2 of the highest sensor can be higher or much higher than the height h1 to which the emission device 201 is fixed. An object of the invention being to position the sensors of the device receiver as high as possible in order to increase the direct visibility and reduce the interference fringes due to reflections on the ground, this aim is therefore achieved thanks to the distinction between the transmitting device and the receiving device.

The sensors of the reception device 21 1 to 215 comprise omnidirectional radiating elements in the horizontal plane, such as for example dipole antennas mounted vertically, which makes the equivalent antenna formed by the network of sensors omnidirectional in azimuth and directive in elevation. Sensors can also be directional if the purpose of the antenna is not to provide 360° surveillance in the horizontal plane. Advantageously, each sensor also comprises a low-noise amplifier making it possible to raise the level of the signal before it is transmitted to the radar processing device 230.

When the cable providing the connection between the transmission device 201 and the radar processing device 230 carries a digital signal, the transmission device 201 comprises a digital to analog converter. Similarly, when the cable 220 providing the connection between the sensors of the reception device 21 1 to 215 and the radar processing device 230 carries a digital signal, the sensors of the reception device each comprise an analog to digital converter. The radar processing device includes the inverse converters.

Advantageously, the link connecting the sensors of the reception device to the radar processing device is an optical link. The use of optical fiber makes it possible to reduce the section and the mass of the cable 220. This solution is preferable to the use of a copper cable because it still makes it possible to lighten the device, and to position the sensors of the receiving antenna as high as possible. It also facilitates the deployment/folding of the reception device. In this case, the sensors also each have converters of the received signals, analog or digital, to optical signals, to transmit the signals acquired by the radiating elements to the radar processing device, as well as, when they include a low-noise amplifier , an optical to electrical energy converter to power it. The radar processing device includes the inverse converters.

The advantages of the embodiment described compared to the state of the art

come from the separation of the transmitting elements and the receiving elements. The mass of the reception device being low compared to that of the transmission device, it can be deployed in height much more easily than if it had been necessary to raise all the transmission/reception equipment.

[0040] In this embodiment, the detection of objects and the estimation of their azimuth, that is to say the determination of their direction and distance in a horizontal plane, are carried out using the coloring properties of the signals issued. This determination is made from the signal received from one of the sensors of the reception device according to methods known to those skilled in the art. Advantageously, the sensor selected for this purpose is the highest sensor, because it is the one for which the interference fringes are the smallest.

Advantageously again, so as to bring gain to the detection in the horizontal plane, this operation is carried out on the signals received from several sensors of the reception device.

[0041] Estimating the azimuth of the detected objects using the coloring properties makes it possible to avoid having to arrange several series of sensors in parallel to create a directional array antenna in the horizontal plane. In this way, the one-dimensional array antenna constituted by the sensors makes it possible to implement 3D localization methods which are usually only possible using two-dimensional array antennas. The transition from two to one dimension therefore makes it possible to reduce the size, cost and complexity of deployment/folding of the device. This also makes it possible to have a larger antenna vertically than known devices at weight constant.

[0042] The detection of objects and the estimation of their elevation, that is to say the

determination of their direction and distance in the vertical plane of the sensors 21 1 to 215 of the reception device, are carried out by the radar processing device 230 from the signals received from all the sensors or from a selection of at least two sensors, using the directivity properties of the array antenna thus formed. The selection of sensors used can be made from considerations relating to the operating frequency band, the spacing between the sensors, as well as the performance in directivity and the gain sought. To determine the position of targets in the vertical plane, the multi-sensor antenna can be used as a directional array antenna scanning the vertical plane, adjusting the phase and amplitude of the signals received from each of the sensors and recombining them to direct the antenna beam. Also, the signals received from at least two sensors can be used by an interferometry process or by high resolution processing.

In practice, the detection can be carried out first in a first plane, for example in the horizontal plane to determine the azimuth of the object, then in a second plane, for example the vertical plane to determine the elevation considering the azimuth determined in the foreground. The detection can also be carried out simultaneously in the two planes, which makes it possible to benefit from a gain in processing making it possible to improve the precision of the measurement.

[0044] Ideally, the reception device is deployed over a length

corresponding to several times the half-wavelength at the maximum frequency envisaged, even several tens or hundreds of times, and includes a large number of sensors. This is possible because the sensors used by the reception antenna do not include power electronics and are therefore very small in size and weight. The receiving antenna can then easily be positioned at very high heights using a balloon 221 of reasonable size, a crane, or any other device making it possible to hang the receiving antenna at a high point, and transport a large number of sensors.

[0045] The significant height of the device makes it possible to significantly reduce

considerable interference fringes and losses for targets at low altitude compared to transmitting/receiving equipment positioned at ground level or at the top of a telescopic mast. The weight of the cable 220 becoming dimensioning when the height of the device increases, it can

advantageously be reduced by being made of optical fiber.

The use of a large number of sensors in the reception device makes it possible to increase the gain of the equivalent antenna and to obtain a very high angular resolution in the vertical plane.

[0047] By way of example, the following table gives the length of the antenna in

depending on the frequency and the number of reception sensors:

[0048] The implementation of a detection device operating for a

frequency of 100 MHz and having 64 sensors therefore requires reception sensors arranged vertically over a height of 95 m, which is restrictive when made from conventional devices such as masts, but that the invention, which dissociates emission and reception and uses the coloring of the signals to limit the number of sensors, makes it possible to achieve low cost by using an airborne device.

FIG. 3 represents a second embodiment of a system for detecting the presence of objects and estimating their direction and distance in three dimensions according to the invention. Unlike the first embodiment, the antenna formed by the reception sensors is not arranged in the vertical plane but in the horizontal plane.

[0050] The emission device 301 is arranged at the top of a telescopic mast

self-supporting by a vehicle, but could be directly installed on the ground. The height h1 of the telescopic mast is constrained by the heavy weight of the emission device. The emitting device comprises several radiating elements, and is configured so as to emit a signal in a colored manner in the vertical plane. This can be achieved from a directional antenna emitting a colored signal whose direction and color vary over time, or from an array antenna comprising several radiating elements each emitting a signal. The antenna beam can be directional or omnidirectional, in the horizontal plane and/or in the vertical plane. It is connected to a radar processing device 330.

[0051] The receiving device comprises several sensors 31 1 separated from the

transmitting device, arranged in line and horizontally, which makes the antenna array formed by the sensor array omnidirectional in elevation and directive in azimuth when the sensors used are omnidirectional in the vertical plane. The sensors of the receiving device are connected by a cable which holds them in position. In this embodiment, the cable is stretched between at least two pylons 321 and 322, so that the sensors are placed at a height h3, but the latter could equivalently each be placed at the top of a pylon or of a mast. The sensors of the reception device are connected to the radar processing device 330 by a cable 320 which carries the signals and the power supplies. This cable can be the same as that ensuring the maintenance of the sensors, or be an independent cable. Alternatively, each sensor can be connected independently to the device 330. Due to the low weight of the sensors, the height h3 at which they are arranged can be greater than the height h1 of the emission device 301. invention being to position the sensors as high as possible in order to increase the direct visibility and to reduce the interference fringes due to reflections on the ground, this object is therefore achieved thanks to the differentiated treatment of the emission device and of the reception.

The sensors 31 1 to 315 of the reception device comprise omnidirectional radiating elements in the vertical plane, such as for example dipole antennas mounted horizontally. Sensors can also be directional if the purpose of the antenna is not to provide 360° surveillance in the vertical plane. Advantageously, each sensor also comprises a low-noise amplifier making it possible to raise the level of the signal before it is transmitted to the radar processing device 330.

When the cable providing the connection between the transmission device 301 and the radar processing device carries a digital signal, the transmission device 301 comprises a digital to analog converter. Similarly, when the cable 320 providing the connection between the sensors 31 1 to 315 of the reception device and the radar processing device 330 carries a digital signal, the sensors each comprise an analog to digital converter. The radar processing device includes the inverse converters.

Advantageously, the link connecting the sensors of the reception device to the radar processing device is an optical link. The use of optical fiber makes it possible to reduce the section and the mass of the cable 320. This solution is preferable to the use of a copper cable because it still makes it possible to lighten the device, and to position the sensors of the receiving antenna as high as possible. It also facilitates the deployment/folding of the reception device. In this case, the sensors of the reception device each have converters of the signals received, analog or digital, towards optical signals, to transmit the signals acquired by the radiating elements to the radar processing device, as well as, when they include a low-noise amplifier, a converter of optical energy supplied by the radar processing device 330 to electrical energy to supply it. The radar processing device 330 comprises the

inverse converters.

In this embodiment, the detection of objects and the estimation of their azimuth, that is to say the determination of their direction and distance in the horizontal plane of the sensors 31 1 to 315 of the reception device, are carried out by the radar processing device 330 from the signals received from all the

sensors or a selection of at least two sensors, using the directivity properties of the array antenna thus formed. The choice of the number of sensors used may depend on the frequency band of the signal, the spacing between the sensors, as well as the desired directivity and gain performance. To determine the position of targets in the horizontal plane, the multi-sensor antenna can be used as a directional array antenna scanning the horizontal plane, adjusting the phase and amplitude of the signals received from each of the sensors and recombining them to direct the antenna beam. Also, the signals received from at least two sensors can be used by an interferometry process or by high resolution processing.

[0056] Ideally, the reception device is deployed over a length

corresponding to several times the half-wavelength at the maximum frequency envisaged, or even several tens of times, and comprises a large number of sensors, in order to increase the gain of the antenna and to obtain a very high angular resolution in the horizontal plane.

[0057] The detection of objects and the estimation of their elevation, i.e.say it

determination of their direction and distance in a vertical plane, are carried out using the coloring properties of the signals emitted. This determination can be made from the signal received from only one of the sensors of the reception device according to methods known to those skilled in the art, which has the advantage of being relatively complex and inexpensive in computing resources. Alternatively, the determination in the vertical plane can be carried out from the coloring properties of the signals received by a plurality of sensors, to benefit from a processing gain making it possible to improve the performance of the detection.

In practice, the detection can be carried out sequentially or

simultaneously in both planes.

Like the first embodiment, the embodiment of FIG. 3 makes it possible to position the sensors of the reception antenna higher than if the entire radar were to be raised. However, it has the defect of presenting an ambiguity concerning the front/rear position of the objects detected in the horizontal plane when the radiating elements of the sensors of

the receiving antenna are omnidirectional in this plane, i.e. the position is determined to within plus or minus p because the antenna pattern is symmetrical with respect to the axis of the receiving antenna. This defect does not appear in the first embodiment where the azimuth of the targets is identified thanks to the coloring properties of the signal and not by using the directivity properties of the reception antenna formed by the various reception sensors. Advantageously, in order to remove the uncertainty about the direction of the objects in the horizontal plane of the second embodiment, means making it possible to make the antenna beam directional can be deployed, such as for example a reflective plane or a dielectric insulator placed one side of the antenna to block and reflect or attenuate the beam in one half of the horizontal plane. Alternatively, it is possible to use directional radiating elements to monitor the horizontal plane only on a horizon lower than TT.

[0060] FIG. 4 represents a third embodiment of a system of

detecting the presence of objects and estimating their direction and distance in three dimensions according to the invention. This differs from that described in FIG. 3 only in that the sensors 41 1 to 416 of the reception device are no longer arranged in line but are arranged so as to form a triangle or any other geometric shape making it possible to lift the ambiguity on the front/rear arrival direction in the horizontal plane.

[0061] By estimating the direction of arrival in the horizontal plane from the sensors of each of the branches of the triangle independently, then by using the three results together, it is possible to remove the ambiguity existing in the device of FIG. In the example of FIG. 4, where the reception device comprises six sensors, a possible implementation consists in estimating the direction of arrival in the horizontal plane from the following triplets of sensors: (41 1 , 412, 413), (413, 414, 415), and (415, 416, 411), then using the ambiguous position information detected by each triplet to resolve the ambiguity on the arrival position in the vertical plane. For a given number of sensors, this determination however leads to a loss in the gain of the antenna compared to the embodiment of Figure 3.

For the rest, the operation of the third embodiment repeats that of the second mode of operation:

- the emission device 301 emits signals in a colored manner in the vertical plane,

- the azimuth of the detected objects is determined by independently considering each of the branches of the triangle formed by the sensors, then by comparing the results to remove the ambiguity on the direction of the detected objects,

- the elevation of the detected objects is determined from the signals received from one or more sensors by considering the color of the signals emitted by the transmitting device. This measurement can, if necessary, be confirmed from the signals received from one or more other sensors.

The processing operations in the horizontal plane and the vertical plane can be carried out sequentially or simultaneously, so as to benefit from a processing gain.

The advantages of the second and third embodiments described in FIGS. 3 and 4 compared to the state of the art come from the separation of the transmitting elements and the receiving elements. The mass of the reception device being low compared to that of the transmission device, it can be deployed in height much more easily than if it had been necessary to raise all the transmission/reception equipment. In addition, the various sensors that make up the device of disappointment can be raised independently of each other.

[0065] The use of optical fiber for the transmission of signals acquired by the

different sensors makes it possible to further lighten the reception device.

Finally, the use of a method for coloring the radar signals emitted in the vertical plane makes it possible to determine the direction of the objects detected in this plane from the signals received from the same sensors as in the horizontal plane, and therefore to considerably reduce the number of sensors required to provide three-dimensional detection. As a result, the cost of the antenna and its complexity of deployment are reduced, and the sensors can be installed at significant heights, thus improving reception conditions.

Thus, the different embodiments of a detection system according to the invention are particularly suitable for the three-dimensional surveillance of theaters of operation. The flexibility and lightness of the reception device, the simplicity of deployment of the radar and the possibility of easily adding sensors to the reception device and of selecting the sensors used to adapt the gain of the reception antenna and its directivity allow it to to have a multi-role capacity that the devices according to the state of the art do not offer.

In addition, the operating frequency of the detection system can be adapted very simply, by selecting a set of sensors from among the sensors of the receiving antenna according to their spacings and the desired wavelength. Since the radar processing device is able to select the sensors from which the detection processing is carried out, the reception antenna can comprise heterogeneous sensors adapted to operate at different frequencies, which confers a multifrequency capability which reinforces the multi-role aspect of the device.

Finally, the radar processing device according to the invention is multi-role

since it makes it possible, from the signals received from the various sensors, to parallelize the implementation of different detection algorithms whose parameters, such as for example the search zone, the data integration time or the operating frequency , are adapted to a specific type of target.

The different embodiments described in Figures 2 to 4 are given here by way of illustration of some of the embodiments of the invention. They do not in any way limit the scope of the invention, which is defined by the claims, and many adjustments obvious to those skilled in the art could be made to the relative arrangement of the various elements, provided that the following principles are respected. :

- Dissociation of transmission and reception equipment,

- Emission in a colored way in a plane, called foreground,

- Implementation of reception by a reception antenna comprising a plurality of sensors arranged in a plane perpendicular to the first plane, each sensor comprising an omnidirectional or non-omnidirectional radiating element in the first plane,

- Determination of the direction of arrival in the foreground using the coloring properties of the signals received from one or more sensors of the receiving antenna,

- Determination of the direction of arrival in a plane perpendicular to the foreground using the directivity properties of the multi-sensor receiving antenna.

[0071] Figures 5a and 5b represent the losses linked to the interference fringes, for equipment located at ground level (Figure 5a) and for equipment placed at a height of 50 meters (Figure 5b). The different filling textures designate the levels of losses linked to the interference fringes, depending on the altitude and the distance from the target.

The interference fringes are linked to the multiple reflections of the signals during its propagation, and to the way in which these paths recombine.

[0073] It is observed in FIG. 5a that the losses at low altitude for a

equipment positioned at floor level vary between -8 dB and -14dB (501 zone). It can be seen in FIG. 5b that these losses are very reduced when the equipment is raised (area 502). This phenomenon is explained in particular by the fact that the direct path is necessarily more marked when the equipment is high.

Thus, the system according to the invention, in which the device for receiving radar signals can be raised at lower cost, has the effect of substantially reducing the interference fringes undergone by the signals, and therefore of improve device performance.

The invention also relates to a method for implementing a

three-dimensional object detection. The method comprises a step 601 of emitting a signal according to a colored emission method in a foreground, such as for example the horizontal plane for an implementation in a scenario corresponding to figure 2, or the vertical plane for figures 3 and 4.

The method includes a step 602 of receiving signals from at

least two sensors arranged in a second plane, perpendicular to the first plane. These sensors can comprise omnidirectional radiating elements in the foreground, for 360° coverage in this plane, or radiating elements covering only part of the foreground.

Finally, the method includes a step 603 of determining the presence of objects and estimating their direction and distance. This determination is carried out in the first plane by exploiting the coloring properties of the signal received by at least one of the sensors. It is carried out in the second plane by exploiting the signals received from at least two of the sensors of the reception device, but the gain of the antenna will be all the more important as the number of sensors considered is large. The exploitation of the received signals can be done by implementing an interferometry process or high resolution processing on the received signals. Alternatively, a directional array antenna can be formed from the different sensors. By varying the direction of the beam of this array antenna, it is possible to scan space to locate the object in the second plane.

CLAIMS

1. System for detecting the presence of objects and estimating their direction and distance according to three dimensions comprising:

- an emission device (201, 301) configured to emit signals according to a colored emission process in a foreground,

- a reception device comprising at least two sensors (21 1 , 212, 31 1 , 312, 41 1 , 412) arranged in a second plane perpendicular to the first plane, and

- processing means (230, 330) of the transmitted and received signals, the detection system being characterized in that the processing means are configured to detect the presence of objects and estimate their direction and distance:

- in the foreground from the signals received from at least one of the sensors of the receiving device by using the coloring of the transmitted signal,

- in the second plane from the signals received from at least two of the sensors of the receiving device,

and in that the transmitting device and the receiving device are separated, the receiving device being elevated relative to the transmitting device.

2. Three-dimensional object detection system according to claim 1, wherein each sensor comprises an omnidirectional radiating element in the foreground.

3. Three-dimensional object detection system according to one of claims 1 and 2, wherein the first plane is a horizontal plane, and wherein the sensors (21 1, 212, 213, 214, 215) are arranged in a vertical plane.

4. Three-dimensional object detection system according to claim 3 wherein the sensors of the receiving device are connected by a cable and suspended under an airborne device (221).

5. Three-dimensional object detection system according to one of claims 3 and 4, in which a single sensor is used to detect the presence of objects and estimate their direction and distance in the foreground.

6. Three-dimensional object detection system according to one of claims 1 and 2, wherein the first plane is a vertical plane, and wherein the sensors (31 1, 41 1) are arranged in a horizontal plane.

7. System for detecting objects in three dimensions according to claim 6, in which the sensors (31 1 , 312, 313, 314, 315) are arranged in line, the system further having means for eliminating ambiguities of the position of the objects relative to the sensors in the horizontal plane.

8. three-dimensional object detection system according to claim 6, wherein the sensors (41 1, 412, 413, 414, 415, 416) are arranged to form a triangle, the detection of the presence of objects and the estimation of their direction and distance in the horizontal plane being carried out for each branch of the triangle respectively, then combined so as to remove ambiguities on the position of the objects relative to the sensors in the horizontal plane.

9. Three-dimensional object detection system according to one of the preceding claims, in which the sensors of the reception device are connected to the processing means by an optical fiber link (220, 320), the sensors further comprising means for converting the received signals to optical signals.

10. Three-dimensional object detection system according to one of the preceding claims, in which the detection of the presence of objects and the estimation of their direction and distance in the second plane comprises the implementation of a method of interferometry or high resolution processing on the signals received from the at least two sensors of the reception antenna, or by exploiting the directivity of an array antenna formed by the at least two sensors of the reception antenna.

1 1. Method for implementing a detection of the presence of objects and for estimating their direction and distance according to three dimensions in a detection system comprising:

an emission device (201, 301) configured to emit signals according to a colored emission method in a foreground,

a reception device comprising at least two sensors (21 1 , 212, 31 1 , 312, 41 1 , 412) arranged in a second plane perpendicular to the first plane, and

means (230, 330) for processing the transmitted and received signals, the method being characterized in that it comprises the separate positioning of the transmitting device and of the receiving device so that the receiving device is raised by relative to the transmission device, and in that it comprises the steps of:

emission (601) of a signal according to a colored emission process in a foreground,

reception (602) of signals from at least two sensors arranged in a second plane perpendicular to the first plane, and

determining the presence of objects and estimating their direction and distance (603) in the foreground by exploiting the coloring properties of the received signal by at least one of the sensors, and in the second plane from the signals received from at least two of the sensors.