SYNTHETIC ANTENNA SONAR AND METHOD FOR FORMING SYNTHETIC ANTENNA PATHWAYS

专利摘要:
The present invention is in the field of sonar imaging and the detection and classification of objects using a synthetic antenna sonar. The sonar (1) with synthetic antenna is intended to move along a first axis (X1). The sonar (1) comprises a transmission device (2) configured to emit, at each recurrence, at least one acoustic pulse towards a area observed in a sectored set comprising at least one sector. the sonar (1) comprises a first physical reception antenna (3) extending along the first axis (X1) making it possible to acquire backscattered signal measurements and a processing device configured to form, on R recurrences, for each sector of the sectorized set, synthetic antenna channels from measurements of signals backscattered by the observed area from acoustic pulses emitted in said sector. The sonar (1) comprises at least one gyrometer. The processing device is configured to correct the variations of the movement of the first receiving antenna during the formation of the synthetic antenna channels of said sectorized assembly by performing an autocorrelation by cross-correlation of the successive recurrences.
公开号:FR3018611A1
申请号:FR1400614
申请日:2014-03-14
公开日:2015-09-18
发明作者:Nicolas Burlet；Nicolas Mandelert；Pierre Guthmann
申请人:Thales SA；
IPC主号:

专利说明:

[0001] The present invention is in the field of sonar imaging and the detection and classification of objects by means of a synthetic antenna sonar. SUMMARY OF THE INVENTION It is more specifically concerned with mine warfare and the detection and classification of mines using synthetic antenna sonar. The question of classification of objects is a difficult problem to solve, especially for bottom mines on a textured seabed, or for stealth mines. The use of a sonar as a high-resolution synthetic side-scan sonar provides an answer to this problem but remains insufficient. By lateral sonar is meant a sonar which emits acoustic pulses along a line of sight having a bearing angle substantially equal to 90 °, that is to say which is substantially perpendicular to the trajectory of a carrier aboard he is on board. The sonar is positioned on one of the flanks of a fish or carrier that is submerged. The carrier can be autonomous or towed by a surface vessel. Very high resolution generally means a resolution of less than 10 cm for a sonar having a frequency greater than 100 kHz. Synthetic antenna sonar is intended to improve resolution at a given range without increasing the linear dimension of the receiving antenna. The principle of synthetic antenna sonar is to use a physical antenna formed by a linear array of N transducers. In this type of sonar, during the advancement of the carrier, a transmitting device, or transmitting antenna, emits P successive pulses in a fixed elementary sector relative to the carrier. The signals received by the N transducers of the physical reception antenna are used at P instants, and therefore at P successive locations to form the channels of the synthetic antenna. The resolution of the images obtained, that is to say the resolution of the synthetic antenna paths, is substantially equivalent to that of a virtual antenna whose length corresponds to about twice the length traveled by the physical antenna during these P antennas. successive moments.
[0002] The construction of synthetic antenna channels is performed by a method of processing backscattered signals measured by the antenna known as "synthetic antenna processing method". This process is conventional for those skilled in the art. To form a synthetic sonar antenna path, the signals measured by the receiving antenna are added using delays corresponding to the direction of the channel formed and the different locations of the antenna transducers as a function of their positions. on the physical antenna and the movement of it.
[0003] The main difficulty in applying the principle of synthetic antenna lies in the determination of lane formation delays. While these delays depend only on the distance and the direction of the target point for a conventional antenna, those of a synthetic antenna depend on the movement of the wearer during its duration of formation.
[0004] Determining the delays is even more difficult than this duration of training, that is to say that the number of recurrence is large, which goes hand in hand with a better resolution. The patent application bearing the publication number FR 2769372 is based on the observation that the accuracy required for measuring the position of the receiving antenna is out of reach of an inertial unit (INS) because the error on the measurement the spatial position of the carrier that she equips is too important. Moreover, it notes that in so-called autocalibration or autofocusing methods which make it possible to obtain the position of the antenna from the processing of the various signals measured by the antenna, the precision on the angle of rotation of the antenna the antenna between two recurrences is the factor limiting the accuracy of the method. It therefore proposes, in order to overcome these drawbacks, a method of correcting the effects of parasitic movements of the antenna in a synthetic antenna sonar, that is to say of correction of the effects due to angular variations of the antenna, in which a synthetic antenna is formed on M sonar recurrences and the variations of the movement of the physical antenna are corrected by performing an intercorrelated autocalibration of the successive recurrences, using the measurement of rotation of the antenna obtained by means of a gyrometer and measuring the elevation angle of the backscattered signal with an auxiliary antenna perpendicular to the physical antenna. This method makes it possible to significantly improve the resolution of the sonar image obtained from the channels of the synthetic antenna. The method, described in the patent application bearing the publication number FR2769372, makes it necessary to equip the sonar with an auxiliary antenna perpendicular to the physical antenna. An object of the present invention is to provide a sonar that allows sonar images having the same resolution as by means of this method but which allows to get rid of an auxiliary antenna. For this purpose, the object of the invention is a sonar (1) with a synthetic antenna intended to move along a first axis, the sonar comprising a transmission device configured to emit, at each recurrence, at least one acoustic pulse towards an area observed in a sectored set comprising at least one sector, the sonar including a first receiving physical antenna extending along the first axis for acquiring backscattered signal measurements from said pulse and a processing device configured to for each sector of the sectored set, forming, on recurrences, synthetic antenna channels from measurements of signals backscattered by the zone observed from acoustic pulses emitted in said sector, the sonar comprising at least one gyrometer characterized in that said processing device is configured to correct variations in the motion of the first antenna during the formation of the synthetic antenna paths of said sectored set by performing cross-correlation self-calibration of the successive recurrences, using measurements of rotation of the first reception antenna obtained with said at least one gyrometer and using estimates of backscattered signal site angles for determining image planes of the backscattered signals and for projecting said rotational measurements onto said image planes, the projections obtained being used to perform the autocalibration, and in which during the formation of the signal paths; Synthetic antenna of at least one sector of the sectorized whole, called bathymetric sector, we use estimates of elevation angles of backscattered signals obtained from a bathymetric map comprising the three-dimensional positions, defined in the terrestrial reference, of a plurality of points of the observed area. Advantageously, the transmitting device) is configured to emit, at each recurrence, acoustic pulses discernable towards an observed zone, in respective different sectors, comprising a first sector and at least a second sector, along a first axis of view. and respectively a second sighting axis having different bearing angles, wherein said at least one bathymetric area 10 comprises at least a second sector, and wherein the bathymetric map is obtained from measurements of first signal angles of first signals backscattered from acoustic pulses emitted in said first sector. The sonar may comprise an array of transducers comprising a plurality of transducers distributed along a second axis perpendicular to the first axis, said transducers forming the array of transducers being dimensioned and configured so that their reception lobes cover the first sector but that said at least a second sector is located at least partially outside their receiving lobes, the first backscattered signals being acquired by means of the transducer array. More specifically, the receiving physical antenna may comprise a first elementary physical antenna formed of first transducers sized and configured so that their receiving lobes cover the first sector but so that said at least one second sector is at least partially located outside of their receiving lobes. The sonar comprises a second basic physical antenna 30 formed of second transducers sized and configured so that their receiving lobes cover the first and second sectors. The processing device is configured to form, during formation of the synthetic antenna channels, channels of a first synthetic antenna from measurements of first backscattered signals from the first sector and acquired by means of the first elementary antenna and channels of a second synthetic antenna from measurements of second backscattered signals from pulses transmitted in said second sector and acquired by means of the second elementary antenna.
[0005] Advantageously, the transducer array is formed by the first elementary antenna and another antenna identical to the first elementary antenna and superimposed on the first elementary physical antenna along the second axis.
[0006] Advantageously, the bathymetric map is obtained by means of a device external to the sonar. The invention also relates to a sonar system comprising the sonar of the invention, and a carrier, the sonar being installed on the carrier. The subject of the invention is also a method for forming synthetic sonar antenna channels on sonar recurrences, the sonar being intended to move along a first axis, the sonar comprising a transmission device configured to transmit at each recurrence, at least one acoustic pulse towards an area observed in a sectored set comprising at least one sector, the sonar comprising a first physical reception antenna extending along the first axis making it possible to acquire backscattered signal measurements from of said at least one pulse and a processing device configured to form, on R recurrences, for each sector of the sectorized set, synthetic antenna channels from measurements of signals backscattered by the observed area derived from acoustic pulses transmitted in said sector, the sonar comprising at least one gyrometer, the method comprising a formation step, in which o n form, for each sector on R recurrences, synthetic antenna channels from measurements of signals backscattered by the observed area resulting from acoustic pulses emitted in said sector, during which, one corrects the variations of the movement of the first receiving antenna during the formation of the synthetic antenna channels of said sectorized assembly by performing an intercorrelated self-calibration of the successive recurrences, using measurements of rotation of the first reception antenna obtained with said at least one gyrometer and using estimates of backscattered signal site angles for determining image planes of the backscattered signals and for projecting said measurements of rotation onto said image planes, the projections obtained being used to perform the self-calibration, and in which during the formation of the signaling channels; synthetic antenna of at least one sector of the sectorized whole, In the bathymetric area, estimates of elevation angles of backscattered signals obtained from a bathymetric map comprising the three-dimensional position of a plurality of points in the observed area are used. Advantageously, the transmission device is configured to emit, at each recurrence, acoustic pulses discernable towards an observed zone, in respective different sectors, comprising a first sector and at least a second sector, along a first axis of view and respectively a second sighting axis having different bearing angles said at least one bathymetric sector comprises at least a second sector. The bathymetric map is obtained from 20 measurements of first elevation angles of first backscattered signals from acoustic pulses emitted in said first sector. The sonar comprising a transducer array comprising a plurality of elementary transducers distributed along a second axis perpendicular to the first axis, said transducers forming the array of transducers being dimensioned and configured so that their receiving lobes cover the first sector but said at least a second sector is located at least partially outside their reception lobes, the first backscattered signals being acquired by means of the transducer array, the method advantageously comprises for each recurrence, a step of measuring first angles of first signals backscattered by means of the transducer array, a step of calculating first angle of elevation estimates, of transposing measurements of the first angles of elevation into a terrestrial frame of reference. The method further comprises a step of producing the bathymetric map from estimates of the first elevation angles, the bathymetric map comprising three-dimensional coordinates, in the terrestrial reference, of probe points having backscattered the first backscattered signals.
[0007] Advantageously, the method comprises a step of estimating the elevation angles of the backscattered signals from pulses emitted in said bathymetric area from the bathymetric map. The method comprises, for each of the backscattered signals, a step of calculating the position of a point Mp of the bathymetric map closest to a portion of a circle Cp obtained by rotation, about the first axis of a point B located on the other line of sight at a distance from the antenna corresponding to the distance separating the antenna from a probe point having generated the backscattered signal, a step of calculating a first point of intersection Ip between the bathymetric map and the circle portion Cp from the nearest point Mp, and a first calculation step, in the terrestrial frame, of the elevation angle of the intersection point. The point of intersection Ip may be the point of intersection between a horizontal plane, in the terrestrial reference, passing through the nearest point Mp, and the portion of circle Cp. Advantageously, the method comprises a second step of calculating a second intersection point Ip between the bathymetric map and the circle portion Cp from the nearest point Mp and other points of the bathymetric map, and if a second intersection point is obtained, a second step of calculating the elevation angle of the second intersection point. The receiving physical antenna may comprise a first elementary physical antenna formed of first transducers sized and configured so that their receiving lobes cover the first sector but so that said at least one second sector is at least partially located outside of the first sector. The channel forming step then comprises a step of forming channels of a first synthetic antenna from measurements of backscattered signals from pulses transmitted in said first sector acquired by means of the first antenna. elementary, in which the estimates of backscattered signal elevation angles used to determine image planes of the backscattered signals and to project said rotational measurements on said image planes are estimates of the first elevation angles of the first backscattered signals, the first backscattered signals being derived from imp ulsions issued in said first sector, the estimates of the first angles of view being transpositions of measurements of the first angles of view in the terrestrial reference.
[0008] The invention finally relates to a computer program product adapted to implement the method according to the invention. The proposed invention eliminates the auxiliary antenna without decreasing the resolution of the synthetic antenna sonar, that is to say without reducing its detection and classification capabilities. Other features and advantages of the invention will become apparent on reading the detailed description which follows, given by way of nonlimiting example and with reference to the appended drawings in which: FIG. 1 schematically represents the elements of an example sonar according to the invention, Figure 2 schematically shows the sonar of Figure 1 installed on a carrier in top view when transmitting 25 acoustic pulses in three sectors, Figure 3 shows schematically, from the side, the first receiving physical antenna and a second sonar receiving antenna of FIG. 1, FIG. 4 schematically represents a site angle of a signal backscattered by a target A as calculated and used in the method according to the invention, FIG. 5 represents a block diagram of an exemplary method according to the invention, FIG. 6 schematically represents the construction of the bathymetric chart. Figure 7 shows schematically the calculation of the positioning of the probe points for the second elevation angle. From one figure to another, the same elements are identified by the same references. The invention relates to a sonar mono-aspect or multi-aspect synthetic antenna. Synthetic antenna single-aspect sonar means a synthetic antenna sonar intended to move along a first axis, the sonar comprising a transmission device configured to emit, at each recurrence, an acoustic pulse towards an area observed in the first axis. a single sector, the sonar comprising a first receiving physical antenna for acquiring backscattered signal measurements from said pulse and a processing device 15 configured to form, on R recurrences, synthetic antenna channels from measurements signals backscattered by the observed area from acoustic pulses emitted in said sector. The acoustic pulses are emitted along a single line of sight in a single sector surrounding the line of sight. This axis of sight may be integral with the antenna or be directed in a fixed direction in the terrestrial reference system, for example by means of a stabilization device. By sector in which an acoustic pulse is emitted is meant the opening sector at -3 dB in which the main lobe of the emitted acoustic pulse is emitted. The use of a synthetic antenna mono-aspect sonar is unsatisfactory for the object classification step detected on the sonar images. By classification is meant the characterization of the nature of the object detected on the image (such as its size and / or shape or the characterization of the object as a mine or non-mine). In order to improve the classification performance, the points of view of the detected objects are multiplied. The more observations of the same object from different angles, the easier it is to classify this object. To multiply the points of view, one solution is to use a multi-aspect sonar with a synthetic antenna. This solution does not require several sonar passes on the observation surface along different paths. It also consumes little energy. Therefore, this solution is suitable for installation on autonomous underwater vehicles. It does not require knowing the absolute positioning of the carrier with great precision or implementing registration techniques to associate different views of the same object between them. It also improves performance in object detection on sonar images. In Figure 1, there is shown the constituent elements of an example sonar 1 according to the invention. In this example, sonar is a multi-aspect sonar. It comprises a transmission device 2, comprising one or more transmitting antennas. The emission device 2 is configured to emit at each recurrence, acoustic pulses to an observed area, for example a seabed. The pulses emitted during a recurrence are issued in a sectored set comprising several sectors. At each recurrence, the emissions emitted in the respective sectors are discernible. For example, the pulses emitted in the respective sectors are emitted with carriers that are distinct from each other, ie located in disjoint frequency bands. As a variant, the pulses are emitted with carriers having the same carrier frequency but are distinguished from each other by orthogonal codes, that is to say by orthogonal modulations. The signals backscattered by the seabed and coming from different sectors are then discernible in the same way as the pulses emitted in these different sectors, for example by filtering or by demultiplexing. At each recurrence, the pulses emitted in the different sectors are, for example, transmitted simultaneously or substantially simultaneously. FIG. 2 shows the sectors S1, S2 and S3 in which the sonar emission device 2 according to the invention emits the acoustic pulses at each recurrence. The transmission device 2 emits 3 pulses in three sectors S1, S2, S3 respectively at each recurrence along the respective axes of sight v1, v2, v3. The sonar 1 is intended to move along a first axis X1 during the emission of acoustic pulses during successive recurrences. The sonar 1 and mounted on a carrier PO. In the embodiment of the figure, the first axis X1 is parallel to the direction X of displacement of the carrier PO. The axes of sight v1, v2, v3 301 8 6 1 1 11 form respective different bearing angles 01, 02, 03 with the first axis X1. Advantageously, the sighting axes v1, v2, v3 have the same elevation angle, the elevation angle being defined in the terrestrial reference system. In a variant, the sighting axes have the same local elevation angle, in the sonar-related reference, that is to say they form the same angle with a plane parallel to the axis X1 and perpendicular to the plane formed by the active surfaces of the transducers. The axes of sight v1, v2, v3 comprise a lateral sighting axis v1 which is substantially perpendicular to the first axis X1, and two additional target axes v2 and v3 which are symmetrical to one another with respect to a plane of symmetry perpendicular to the direction of advance X and passing through the axis v1. In other words, the bearing angle θ1 of the axis v1 is equal to 90 °. It will be called later the lateral axis of sight. The axes v2 and v3 form, for example, angles θ of -35 ° and 35 ° respectively in 15 bearing with the axis v1. Alternatively, the additional target axes are not symmetrical to each other with respect to the plane of symmetry. The axis v2 is called the line of sight forward and the line of sight v3 is called the line of sight to the rear. The misalignment of the sighting axes v2 and v3 with respect to the first axis v1 is obtained electronically or mechanically. In the latter case, the transmission device comprises three transmitting antennas pointing along three different axes of aim. In the embodiment of FIG. 2, sectors S1, S2, S3 are disjoint. The openings of the adjacent sectors are smaller than the angle formed between the two sectors in the reference plane. Advantageously, the angular aperture of each sector is small, that is to say less than 10 °. These features help to minimize backscattered signal processing costs by limiting the total size of the insonified sector while maximizing the effective total sonar hourly coverage. In general, the opening of the sectors must be wide enough to obtain the desired resolution at the sonar emission frequency. Limiting the width of the insonified sector makes it possible to limit the pitch between the hydrophones of the first receiving antenna and therefore their number and their cost. Alternatively, the sectors are joined or overlap partially two by two. The sectors S1 to S3 have, for example, the same opening in the field and the same opening in site. In a variant, the sectors have openings in the field and / or in different sites. The number of sectors is alternatively different from 3, for example equal to 5 or 2. The important thing is that at each recurrence, the transmission device 2 emits discernible acoustic pulses in the respective sectors comprising at least a first sector and another sector distinct from the first sector. The sonar 1 comprises a first physical reception antenna 3 for measuring the signals backscattered by the seabed and originating from the acoustic pulses emitted in the different sectors at each recurrence. The sonar 1 also comprises a processing device 4, comprising for example at least one computer, configured to form the channels of a synthetic antenna for each of the sectors. In other words, the processing device 4 is configured to form synthetic antenna paths, which consists in forming, for each sector, synthetic antenna channels from measurements of backscattered signals originating from acoustic pulses emitted. in the sector considered, that is to say from measurements of signals backscattered by the area observed in the sector considered. The processing device 4 is configured to form, on R recurrences, the channels of a first synthetic antenna based on measurements of the backscattered signals originating from acoustic pulses emitted in the first sector S1 and the channels of at least one other antenna. synthetic, the channels of each other synthetic antenna being formed from the measurements of backscattered signals from acoustic pulses emitted in one of the other sectors. The measurements of the backscattered signals used are measurements made by the first reception antenna 3. In the case represented in FIG. 2, the processing device 4 thus forms the channels of three synthetic antennas, one for each of the sectors S1, S2, S3.
[0009] In FIG. 2, the first receiving antenna 3 is positioned on the starboard side, the emission device 2 emitting acoustic pulses on the starboard side. Alternatively, the sonar includes two transmitting devices, one transmitting port and one transmitting starboard, and two receiving antennas, one to port and one to starboard.
[0010] The first receiving antenna 3 is a longitudinal antenna extending linearly along a first axis X1. The first axis X1 is substantially parallel to the direction X of advancement of the carrier PO. The receiving antenna comprises N + M sensors. It comprises, in general, one or more physical receiving antennas elementary. In Figure 3, there is shown a side view sonar receiving antennas according to the invention. The first receiving antenna 3 is a composite antenna formed of a linear array of N + M transducers. It comprises a first elementary antenna 5 which comprises a linear array of M (here 4) first identical transducers T5 spaced along the first axis X1 and a second elementary antenna 6 comprising a linear array of N (here 4) second spaced identical transducers T6 along the first axis X1. The first transducers T5 are separated in pairs by a second transducer T6 along the first axis X1 and the second transducers T6 are separated in pairs by a first transducer T5 along the axis X1. In other words, the linear array of N + M transducers along the axis X1 alternately comprises, along the first axis X1, a first transducer and a second transducer. The consecutive transducers are separated from a space having a fixed length e along the first axis so that the first pitch P5 between the first transducers is equal to the second pitch P6 between the second transducers. In the embodiment of FIG. 3, the first transducers T5 have a width L5 greater than the width L6 of the second transducers T6 along the first axis X1. Consequently, the aperture of the receiving lobes of the first transducers T5 of the first elementary antenna 5 is smaller than the opening in the bearing lobes of the second transducers T6 of the second elementary antenna 6. Advantageously, the first Transducers T5 are dimensioned and configured so that only the first sector S1 is included in their receiving lobes and so that the other sectors S2, S3 are located outside the reception lobes of the first transducers T5 constituting the first elementary antenna 5. In other words, the first transducers have a directivity that allows the first antenna 5 to image the first sector S1 but which does not allow to simultaneously image the other sectors. On the other hand, the signal-to-noise ratio of the first elementary antenna is greater than the signal-to-noise ratio of the second antenna. The bearing aperture of the transducers of the first elementary antenna 5 is advantageously substantially equal to the bearing aperture of the first sector S1. Alternatively, the first transducers T5 are sized and configured so that the first sector is included in the receiving lobes of the first transducers T5 of the first elementary antenna 5 and so that the other sectors S2, S3 are at least partially included. in the reception lobes of the first transducers T5 of the first elementary antenna 10. This variant generates a synthetic first antenna having a lower signal-to-noise ratio but a lower cost. The elementary antennas 5, 6 each make it possible to measure the backscattered signals originating from all the pulses emitted during a recurrence by the transmission device 2. The processing device 4 is configured to discriminate the backscattered signal measurements. by the background from the respective pulses and to generate the channels of three synthetic antennas. The processing device 4 comprises a first module 40 making it possible to discriminate the measurements of the backscattered signals according to the sectors of the acoustic pulses from which they originate, ie sectors in which the targets which have backscattered the signals are located, and a second module 41 for generating the channels of the synthetic antennas from measurements of these signals backscattered in the respective sectors. The second module 41 is configured to generate the channels of the first synthetic antenna from first 25 measurements of first signals backscattered by the observed area from pulses transmitted in the first sector S1, said first measurements being acquired by the first elemental antenna 5. The second module 41 is configured to generate the channels of the second and third synthetic antennas from second measurements of backscattered signals 30 from pulses transmitted in the second and third sectors S2 and S3 the second measurements being acquired by the second elementary antenna 6. This arrangement and the associated processing mode make it possible to obtain a first synthetic antenna of high resolution and having a very good signal-to-noise ratio and other synthetic antennas having very high resolution without having to sample excess the receiving antenna, that is to say without providing an inter-transducer pitch whose value would be of the order of the half-wavelength of the acoustic pulse used. This makes it possible to limit the number of transducers required, which has advantages in terms of cost and energy expenditure. The processing device 4 also makes it possible to generate an image representing the synthetic antenna paths of each synthetic antenna. These synthetic images are, for example, but not necessarily scrolling images (so-called "waterfall" in English terminology). They represent the synthetic antenna paths on R recurrences and at the R + 1 recurrence, the recurrence index 1 disappears from the screen to reveal the representation of the R + 1 recurrence. These images are not focused on a particular point in the geocentric repository. They thus have the advantage of allowing an object detection and not just a classification of a previously detected object. They represent a number of points of view of an observed area equal to the number of sectors, the points of view being acquired substantially simultaneously. The sonar 1 according to the invention comprises a display device 10 for simultaneously displaying said synthetic images. It allows an operator to simultaneously observe different synchronized points of view of an observed area which facilitates object detection and classification operations. The modules are for example calculation functions of the same computer or different computers. The first module may include filters and / or a demultiplexer. As for single-aspect sonars, the resolution of the synthetic antennas of a multi-aspect sonar is limited by the deviations of the receiving antenna from a straight and uniform navigation path. Consequently, the formation of the channels of each of the synthetic antennas is carried out by correcting the effects of the parasitic movements of the receiving antenna 3 by using the correction principle described in the patent application FR 2769372. The processing device 4 is configured so that correction of the motion variations of the first physical receive antenna 3 is performed for each synthetic antenna by performing cross-correlation autocalibration of the successive recurrences, using measurements of the rotations of the receiving antenna between successive recurrences obtained by means of at least one gyrometer 9 and using estimates, in the terrestrial frame of reference, of elevation angles of signals backscattered between these two recurrences. Each gyrometer is for example part of an inertial unit 9. The set of gyrometers advantageously forms an inertial unit. FIG. 4 shows a terrestrial reference x, y, z 10 representing the vertical direction in the terrestrial reference frame and the plane (x, y) a horizontal plane in this same reference frame. The angle of elevation y, that is to say the angle of elevation defined in a terrestrial reference, of a signal backscattered by a target A is, in the present patent application, the angle formed between the image plane PI which is the plane containing the target A and the first axis X1, and the horizontal plane (x, y). The elevation angles or sidelights of the backscattered signals correspond to the elevation angles of the antenna image planes, or sighting planes, defined for the aiming points that generated these backscattered signals. In the sonar according to the invention, at each recurrence, estimates of backscattered signal angle angles are used to define the image planes of the backscattered signals and to project the measurements of rotation obtained by means of the gyrometers on the image planes obtained. as described in the application FR 2769372. It is then estimated from the projections of the rotation measurements obtained by a conventional autocalibration method, the parameters I and r for each synthetic antenna where T is the difference in propagation times go and return of the sonar pulse for the same point of reflection on the observed area (here the seabed), between two successive recurrences, I is the longitudinal displacement of the receiving antenna, along the first axis X1, between two successive recurrences. These parameters make it possible to correct the variations of the movement of the physical antenna during the formation of synthetic antenna paths. The same method is used in the case of single-aspect sonars. By autocalibration method is meant a method that determines these coefficients from measurements of the backscattered signals acquired by the receiving antenna. Among them, we know in particular methods exploiting the intercorrelation of the acoustic field on the antenna on two successive recurrences. When the longitudinal displacement between two recurrences is less than half the length of the receiving antenna, the field at the leading end of the first recurrence is strongly correlated with the field at the back end. The length Lc of the two correlated ends of the field of the antenna is then given by the formula: Lc = L - 2. V. Tr. Such a method exploits this correlation to estimate the longitudinal displacement I, the difference T of the times of to forward and backward propagation of the sonar pulse for the same point of reflection on the bottom, and the rotation p of the aiming direction, between the two recurrences. An example of such a method is described in US Pat. No. 4,244,036 (Raven). The use of the elevation angles of the backscattered signals to form the channels of the various synthetic antennas thus makes it possible to obtain synthetic antenna channels and synthetic images having a very high resolution. In summary, the estimates of the elevation angles of the backscattered signals are used to project the rotational measurements obtained by the gyrometer (s) onto the image planes of the backscattered signals, the projections obtained being used to perform the self-calibration. . The projections of the rotation measurements on the image planes are the only data needed to generate the synthetic antennas by performing self-calibration. The use of projections of the rotation measurements on the image planes makes it possible to obtain synthetic antenna channels having a better resolution than by using the rotational measurements obtained by means of the gyrometers. This method makes it possible to improve the resolution of the sonar image obtained from the channels of the synthetic antenna. The site angles are defined in the terrestrial reference system. According to the invention, during the formation of the synthetic antenna channels of at least one sector of the sectorized set, called the bathymetric sector, use is made of backscattered signal angle estimates taken from among said estimates of angles of elevation used in forming pathways of at least one of the synthetic antennas. The estimates are obtained from a bathymetric map comprising three-dimensional positions defined in the terrestrial reference frame of respective points of the observed zone.
[0011] According to the invention, it is possible, for example, to provide that all the insonified sectors are bathymetric sectors or that the only insonified sector (single-aspect case) is a bathymetric sector. The invention has the advantage of making it possible to dispense with an auxiliary antenna, as described in patent application FR 2769372, having a plurality of sensors distributed along an axis perpendicular to the axis of the first receiving antenna. . For example, a pre-existing bathymetric map of the observed area stored in a sonar memory can be used before imaging the observed area. This bathymetric map can be derived from a bathymetric map atlas or from a survey of a hydrographic vessel. Alternatively, the bathymetric map can be obtained by means of a multibeam sounder or other lateral sonar, for example, without a bathymetric capacitance or by means of a sonar altitude measuring device associated with a hypothesis that the observed area has a constant altitude. In these last three cases, the bathymetric map can be constructed during sonar recurrences or before recurrences. In summary, the bathymetric map can be obtained by means of a sonar external system according to the invention. Advantageously, the sonar is devoid of an auxiliary antenna having a plurality of sensors distributed along an axis perpendicular to the axis of the first receiving antenna. Such a sonar presents a reduced cost both at the material level and at the treatment level, a reduced bulk, a reduced mass, consumes a reduced energy due to the reduction of the cost of the treatment and the reduction of the bulk and the mass. . As a variant, the sonar according to the invention comprises an auxiliary antenna as described in the patent application FR 2769372. According to one particular embodiment concerning the multi-aspect sonar as described above, use is made of estimates of elevation angles obtained at from the bathymetric map to correct the variations of the movement of the first receiving antenna during the formation of the channels of sectors S2 and S3 or at least one of these two sectors. The bathymetric map can be constructed by various means, for example by means of a device external to the sonar.
[0012] Advantageously, the first angle of elevation measurements used to estimate the elevation angles are measurements of the first field angles of backscattered signals coming from the first sector, that is to say coming from acoustic pulses emitted in the first sector. By estimating the elevation angles of the backscattered signals originating from pulses emitted in sectors S2 and S3 from first measured elevation angles for backscattered signals originating from acoustic pulses emitted in the first sector, it is possible to obtain, for these sectors S2, S3, synthetic images having a much better resolution than without making correction of the parasitic movements of the receiving antenna during formation of the synthetic antenna path corresponding to these sectors and similar to those which would be obtained using angle of elevation measurements obtained directly by an auxiliary antenna whose receiving lobe would cover these sectors. According to a particular embodiment, the bathymetric map is obtained from measurements of first elevation angles of first backscattered signals acquired in the first sector S1. The measurements of the first angles of elevation are obtained by means of backscattered signal measurements obtained by means of an array 11 of transducers T5, T7 comprising a plurality of transducers distributed along a second axis Z2 perpendicular to the first physical reception antenna 3, that is, perpendicular to the first axis X1. In other words, the network 11 comprises a stack of transducers in the direction Z2. Such a distribution of the transducers makes it possible to measure the first elevation angles of the backscattered signals since the array 11 of transducers has a directivity along the axis Z2. The signal-to-noise ratio on the angle of elevation measurements made by this antenna is significantly higher than that obtained on the receiving antenna 3. The axis Z2 is perpendicular to the first axis X1 and is parallel, locally, to the plane the first physical antenna, that is to say the plane formed by the transducer membranes 5, 6. The Z2 axis is parallel to the vertical axis z defined in a terrestrial reference, when the base of the receiving antenna 3 is zero. Preferably, the network 11 has, along the axis Z2, a height greater than the height of the first receiving antenna 3.
[0013] Advantageously, the transducers T5, T7 forming the array 11 of transducers are dimensioned and configured so that only the first sector S1 is fully included in their receiving lobes. We will see that this limits the number of sensors required, and therefore the cost of sonar, while allowing to obtain the synthetic images and synthetic antenna channels of very high resolution. By configuration of the transducers is meant their positioning relative to the receiving antenna and their pointing directions. In other words, the transducers of the array 11 of transducers are dimensioned and configured so that the first sector S1 is comprised, in alignment, in their main reception lobes and so that the other sectors S2, S3 are at least partially located, in deposit, apart from their main receiving lobes. Advantageously, the opening in the field of the receiving lobes of the transducers of the array 11 is substantially equal to the opening in the bearing of the first sector S1. In the embodiment of FIG. 3, the other sectors S2, S3 are located completely outside the main lobes of the transducers forming the transducer array 11. In this figure, the sonar 1 according to the invention comprises a second receiving antenna 12. This second receiving antenna 12 is a physical antenna identical to the first elementary antenna 5 and superimposed on the first elementary antenna 5 along the second axis Z2. It comprises third transducers T7 distributed along a third axis X3 parallel to the first axis X1. The third transducers T7 are identical to the transducers T5 and spaced at the same pitch along the axis X1. The array 11 of transducers by means of which the first elevation angles are measured comprises the transducers of the first elementary antenna 5 and the second elementary antenna 12. In other words, the transducer array 11 is formed by the first elementary reception antenna 5. and by the second receiving antenna 12. These two antennas constitute an interferometric antenna. In a variant, the second receiving antenna 12 is shorter along axis X1 than the first receiving antenna. In other words, it has fewer sensors along the X1 axis. In another variant, the second receiving antenna 12 has transducers having a different size in the direction X1 and / or in the direction Z2 than the first transducers T5. In another variant, the array 11 of transducers having a single transducer in the direction X1 and a linear array of transducers spaced along the axis Z2. The array of transducers comprises, or not, one of the transducers of the first receiving antenna 3. These antennas, however, have no selectivity in the field and make it possible to obtain synthetic antenna paths that are less well resolved in the field. The transducers forming the array 11 can extend linearly along the second axis Z2 or form a curved surface adopting the curve of the cylindrical shell but having an extension along the second axis Z2.
[0014] In summary, the transducers forming the array 11 of transducers are configured and dimensioned so that the network 11 does not allow direct access to estimates of the elevation angles of the backscattered signals by targets located in all sectors S1, S2, S3 but only in one of these areas. In the non-limiting example of the patent application, this sector is sector S1, that is to say the lateral sector. This solution is economical from a software point of view and from a hardware point of view because it does not require a network of transducers to cover all sectors. It is, for example, more economical than a solution consisting in forming an interferometric antenna from the first receiving antenna and a second identical receiving antenna superimposed on the first receiving antenna in the Z2 direction. The number of transducers of the second receiving antenna would be doubled with respect to the number of transducers of the second sonar receiving antenna according to the invention which would be more expensive from a material point of view, from the point of 301 8 6 1 1 22 view clutter and from the point of view of data processing. On the other hand, the proposed solution based on the network 11 according to the invention constituting an interferometric antenna makes it possible to obtain angles of elevation, in the first sector S1, with a resolution identical to that of an interferometric antenna which would be obtained by superimposing the first receiving antenna 3 and another identical antenna. The proposed solution does not require an expensive interferometric antenna sampled along the axis X1. The invention also relates to a synthetic antenna formation method of a sonar according to the invention on Sonar recurrences. The sonar described above is able to implement the method according to the invention. Figure 5 shows a block diagram of this process. The channels are formed from the measurement signals obtained from R recurrences. The method comprises, at each recurrence r with r = 1 to R, a step 100 of emission of acoustic pulses detectable in each sector S1, S2, S3, by means of the emission device 2, during the advance of the sonar 1 according to the axis X1, a step 101 of acquiring signal measurements backscattered by the area observed by means of the first receiving antenna 3, a step 102 of discriminating the measurements of the signals acquired by the first antenna of receiving, for example, by means of the first module 40, which may be subsequent to step 103, a step 103 of storing the measurements of the signals acquired by the first reception antenna 3, for example in a first memory 70, a step 104 for measuring rotations (roll, pitch and yaw) of the first receiving antenna or the carrier PO by means of at least one gyrometer, a step 105 of storing the rotation measurements, for example in a second m 71, which may or may not be the first memory, a step 106 for measuring the position of the carrier, or the receiving antenna 3, in a terrestrial frame by means of a position measuring device 72. allows to obtain the position measurements in latitude, longitude and immersion of the carrier PO in a terrestrial reference system, a step 107 of storage of the position measurements of the sonar, for example, in a third memory 73, which may or may not be the first memory and / or the second memory. The method also includes a synthetic antenna channel formation step 120, 121, 122 from backscattered signal measurements acquired by the first receive antenna 3 over successive recurrences of the sonar 1. The method also includes step 130, 131 132, 131, 132. In the case of a single-aspect sonar, step 102 is not implemented, step 120, 121, 122 is a step of forming a synthetic antenna and step 130, 131, 132 is a step of forming the associated synthetic image. The invention relates to a method comprising a step 120, 121 121, 122 of formation, on R recurrences, channels of each synthetic antenna corresponding to the sonar considered from the measurements of signals backscattered by the observed area from acoustic pulses issued in each sector. In this step, the variations of the motion of the first receiving antenna are corrected during the formation of synthetic antenna paths as explained above. According to the invention, during the formation of the channels of at least one synthetic antenna, use is made of the elevation angle estimates of backscattered signals obtained from a bathymetric map comprising three-dimensional positions of a plurality of observation points. the area observed. 3 0 1 8 6 1 1 24 We will now describe the other steps of the method according to the invention in the case of the multi-aspect sonar in which we build the channels of the synthetic antennas corresponding to the second and third sectors from a map bathymetric obtained from 5 measurements of first angles of elevation obtained by means of the array 11 of transducers. The invention relates to a method for forming the channels of the synthetic antennas corresponding to the step 120, 121, 122. The step 120, 121, 122 of forming the channels of the synthetic antennas on R Io successive recurrences comprises, a step 120 for forming the channels of the first synthetic antenna from measurements of first backscattered signals from the first sector S1 and of the channel formation steps 121, 122 of the two other synthetic antennas from second measurements of second and third signals, respectively. backscattered from the acoustic pulses emitted in the second and third sectors, respectively, in which the motion variations of the first reception antenna are corrected by performing cross-correlation self-calibration of the successive recurrences using measurements of rotation of the reception antenna obtained by means of said at least one gyrometer and in u using, to determine second and third image planes, estimates of second and third site angles of backscattered signals calculated from a bathymetric map. The rotation measurements are then projected onto the second and third image planes and used to perform the self-calibration associated with the second and third synthetic antenna respectively. The bathymetric map is for example obtained from measurements of the first angles of elevation. Steps 120 to 122 are performed by the second module 41. These steps 120, 121 122 are preceded by a discrimination step, performed by means of the first module 40 to discriminate the measurements of the signals according to the sectors of the acoustic pulses for which they are used. are from. Each step 120, 121, 122 comprises a step, not shown, of selecting the signals necessary for the formation of the channels of the synthetic antenna considered among the signals measured by the first physical antenna 3. 3 0 1 8 6 1 1 25 The method also comprises, prior to steps 120, 121, 122, a step 108 performed for each recurrence, for measuring first angles of elevation of the first signals backscattered to a number P of times of probe tp, with p = 1 to P spaced apart two by two of a predefined basic period 5 T and starting at a first probe time t1 subsequent to the emission time of the associated acoustic pulse and spaced therefrom by a predefined duration D. In other words, at each recurrence, first site angles of first signals are measured backscattered by P probe points Pp measured by the first reception antenna 3 at 10 instants of probe tp. These measurements are made in the grid reference 11 by the network 11. In the case of FIG. 3, the first elevation angles are estimated from first measurements of the first backscattered signals made by the first elementary antenna 5 and from additional measurements of the first backscattered signals made by the second reception antenna 12 during a recurrence. The channel formation step 120 of the first synthetic antenna is made from first measurements of first backscattered signals from pulses transmitted in the first sector during the recurrences. The first measurements are carried out, in the embodiment shown in the figures, by means of the first elementary reception antenna 5. During this step, the variations of movement of the reception antenna are corrected by performing an autocalibration by intercorrelation of successive recurrences. To correct these variations, the measurement of the rotations of the receiving antenna obtained with said at least one gyrometer is used and estimates of the first angles of elevation of the first backscattered signals emanating from acoustic pulses emitted in the first sector S1 are used. to determine the first image planes on which the rotational measurements obtained by means of the gyrometer are projected so as to obtain the projections which are used to carry out the self-calibration of the first synthetic antenna. The estimates of the first elevation angles correspond to the measurements of the first elevation angles made by the transducer array 11 and transposed, during step 110, into the terrestrial frame of reference from the measurements of position and rotations of the sonar made during the Steps 104 and 106. This method makes it possible to obtain channels of the first synthetic antenna having a very high resolution identical to the channels of a conventional synthetic antenna whose variations in the movement of the antenna. The method comprises a step 111a for producing the bathymetric map of the zone observed from the estimates of the first angles of elevation obtained during the recurrences and a step 111b of the bathymetric map, for example in a fourth memory 74. The bathymetric map includes a set of positi 3-dimensional onsets of Pp probe points in the terrestrial repository. Step 111 consists, for each recurrence, in positioning in a terrestrial reference point probe points at the origin of the first backscattered signals measured at the recurrence considered, from the measurements of the first angles of view made during step 108 and measurements of measured positions and rotations made during steps 104, 106, or from the estimates of the first elevation angles in the terrestrial frame obtained in step 110. In FIG. 6, there is shown , by rounds, the positions of the probe points Pp with p = 1 to 6 in a terrestrial reference x, y, z, obtained at each recurrence, the trajectory TS 20 of the carrier PO and the positions of the carrier PO at each recurrence r (r = 1 to 5). For clarity, the positions associated with the even recurrences have a white background and the positions associated with the odd recurrences have a gray background. For each recurrence, in solid lines, the limits of the first sector S1 are represented in the vertical plane y, z comprising the first axis of view v1 and in dotted lines the line Ir (with I = 1 to 5) included in FIG. this plane and passing through the probe points Pp positioned for said recurrence. The dotted lines Ir, corresponding to the different recurrences, are not parallel to each other because the trajectory of the wearer is not exactly straight. The three-dimensional mesh formed by the probe points is not necessarily regular in the plane x, y, because of rotations and / or change of speed of the carrier. For clarity, the positions of the probe points Pp are referenced only for the first recurrence. The method comprises a step 112 for estimating, for each recurrence, second angles of elevation of second backscattered signals measured by the second elementary antenna 6 at P instants of probe tp, with p = 1 to P spaced two by two from a predefined basic period T and starting at a first probe time t1 subsequent to the moment of emission of the corresponding second acoustic pulse and separated from the latter 5 of the duration D. It also comprises a step 113 for estimating third angles of elevation of third backscattered signals measured by the second elementary antenna 6 at P instants of probe tp, with p = 1 to P spaced two by two from a predefined elementary period T and starting at a first instant probe t1 posterior to the moment of emission of the corresponding third acoustic pulse and separated from the latter of the duration D. These steps are carried out from e the bathymetric map and measurements of the position and attitude of the wearer during the recurrences performed during steps 104, 106 relating to the corresponding recurrence. Steps 121 and 122 use, to improve the accuracy of the rotational measurement obtained by the gyro, the estimates of the second and third angles of elevation, respectively. We will now describe step 112 of estimating second angles of elevation. Step 113 for estimating the third elevation angles is performed in the same way, but from the backscattered signals from the third sector S3. It will not be precisely described. Step 112 comprises, for each recurrence and for each instant of probe tp, a step 112p for estimating the second angle of elevation of a second backscattered signal of an acoustic pulse emitted in the second sector S2 and measured by the first antenna receiving 3 to 25 at the time of probe tp. This step 112p comprises: a step 112a for calculating the position of the point Mp of the bathymetric map closest to the position of the probe point Pp from which the second backscattered signal originates by determining the position of the point of the bathymetric map, closest to the portion of a circle Cp obtained by rotation of a point B located at a distance pp from the center O of the receiving antenna 3 along the second viewing axis v2 about the first axis X1, the distance pp being the distance to separate the probe point Pp from the center O of the first receiving antenna 3 so that the first receiving antenna measures the second signal backscattered by the probe point Pp at the probe time tp, a step 112b calculating a point of intersection Ip between the bathymetric map and the circle portion Cp from the point Mp, the point Ip corresponding to the estimated position of the probe point having backscattered the second signal; ape 112c for calculating the angle of elevation of the point Ip, in the terrestrial reference system from the position of Ip, the position measurement of the carrier Po or the receiving antenna 3 and in particular its relative altitude at the seabed and distance pp. The circle Cp is located in a PC plane perpendicular to the axis X1. In FIG. 7, there is shown the circle Cp containing the points located at a distance pp from the center O of the antenna and having a bearing angle Op of 55 ° as well as the nearest point Mp and the intersection Ip between Cp and the bathymetric map CB. The known points of the bathymetric map CB are the points of intersection of the grid Q. The portion of the circle used is the portion of the circle located on the starboard side but one could also use the whole circle Cp. The circle Cp is an estimate of the location of possible positions of the probe point Pp at the origin of the second backscattered signal. This is the set of points of a cone whose axis is the axis X1 and having a generatrix having a bearing angle equal to that of the second axis of sight v2 which are located in the plane PC. In other words, this amounts to estimating, during step 112, second angles of elevation of second backscattered signals emanating from acoustic pulses emitted along the second sighting axis v2, 02 and located at the distance pp from the center of the antenna of reception 3. The bathymetric map must be memorized on a minimum number Nm of recurrences which makes it possible to position the Pp probe points for the current recurrence during the step of estimating the third angles of elevation (i.e. during the step of estimating the elevation angles for the rear mode). This number is the number of recurrences required when the mean rotation of the sonar on its trajectory is zero and it advances at the minimum speed Vmin (least favorable case): 35 Pmax is the maximum range of the sonar (it is a distance maximum relative to the center of the antenna called oblique distance), Os is the relative bearing angle between the first sighting axis v1 and the rear sighting axis v3. Tr is the time interval between two successive recurrences. As soon as the bathymetric map is made for Nm recurrences, the estimation of the elevation angles for the current recurrence for the rear mode and the formation of the third synthetic antenna path for the current recurrence, carried out using these angles of elevation , can start. For the forward mode (forming the channels of the second synthetic antenna), the calculation of the elevation angles can not begin directly because the zone observed by the sonar along the second sighting axis v2 is located in front of the zone explored in lateral mode ( according to v1).
[0015] All measurements of position, rotation and backscattered signals must be kept in memory on Nm recurrences awaiting the construction of the bathymetric map corresponding to the zone targeted by the second axis v2 at the current recurrence. Advantageously, step 112 comprises, for each recurrence and for each instant tp of order greater than 1, before step 112a, an unrepresented step of extracting a portion of the bathymetric chart smaller than the bathymetric map. , the steps 112a and 112b are made from the portion of the bathymetric map. This step speeds up processing times. In a non-limiting example, the entire bathymetric map is used for tp such that p = 1, then, for higher order instants tp, a portion of the bathymetric map located at a horizontal distance less than a predetermined threshold of the point is used. of intersection obtained at the lower order instant.
[0016] Step 112a is performed by calculating the distance of each point of the bathymetric map (or the bathymetric sub-map) and the circle (or arc). We then obtain the point Mp which is the point of the bathymetric map closest to the considered portion of the circle Cp. Step 112b is for example performed by calculating the point of intersection Ip between a Nm = 1+ Pmax sinK 1) 1 Vinin.Tr 301 8 6 1 1 30 horizontal plane (parallel to the plane (x, y)) passing through the point Mp and the portion of circle Cp. This amounts to approximating the bathymetric map by a horizontal plane in the neighborhood of Mp. This step could be carried out more precisely by using several points of the bathymetric map to estimate the area formed by the bathymetric map in the vicinity of Mp. In a first embodiment, the estimate of the second angle of elevation is the angle calculated during step 112c. In a variant not shown, step 112 comprises the step 112a for calculating a first point Mp, a first step 112b for calculating a first intersection point lp, and a first calculation step 112c. a first angle of elevation, in which the point Ip is calculated from the horizontal plane passing through the point M. The step 112 also comprises a second step 112b of calculating a second point of intersection in which one seeks a second intersection point between the second portion of the circle Cp and a surface formed from the point M and other points of the bathymetric map to improve the accuracy of the positioning of the point Ip and if this step converges a second step calculation of angle of elevation, in the terrestrial reference, of the second point of intersection. The second angle of elevation is then the elevation angle calculated for the second point of intersection. This method provides more accurate elevation estimates. Advantageously, the steps 112p are carried out for each instant tp starting at a start time and scanning the instants in the increasing direction until the last moment (p = P) and scanning the instants, since the previous moment l starting moment, in the decreasing direction until the first instant (p = 1), the start time being different from the first instant and the last moment. This method makes it possible to gain in robustness.

权利要求:
Claims (14)
[0001]
REVENDICATIONS1. Sonar (1) with a synthetic antenna intended to move along a first axis (X1), the sonar (1) comprising a transmission device (2) configured to emit, at each recurrence, at least one acoustic pulse to an observed area in a sectored set comprising at least one sector, the sonar (1) comprising a first physical reception antenna (3) extending along the first axis (X1) making it possible to acquire backscattered signal measurements originating from said pulse and a processing device (4) configured to form, on R recurrences, for each sector of the sectored set, synthetic antenna channels from measurements of signals backscattered by the observed area resulting from acoustic pulses emitted in said sector , the sonar (1) comprising at least one gyrometer, characterized in that said processing device (4) is configured to correct the variations of the movement of the first antenna of r ception during the formation of the synthetic antenna channels of said sectorized assembly by performing an intercorrelated autocalibration of the successive recurrences, by using measurements of rotation of the first reception antenna (3) obtained with said at least one gyrometer and using backscattered signal elevation angle estimates for determining image planes of the backscattered signals and for projecting said rotational measurements onto said image planes, the projections obtained being used to perform autocalibration, and wherein during the formation of the backscattered signals, Synthetic antenna channels of at least one sector of the sectorized ensemble, called the bathymetric sector, use is made of the elevation angle estimates of backscattered signals obtained from a bathymetric map comprising the three-dimensional positions, defined in the repository of a plurality of points of the observed area.
[0002]
2. Sonar according to claim 1, wherein the transmitting device (2) is configured to emit, at each recurrence, acoustic pulses discernable to an observed area, in different sectors (S1, S2, S3), comprising: a first sector (S1) and at least a second sector (S2, S3), according to a first sighting axis (v1) and respectively a second sighting axis (v2, v3) having different bearing angles, wherein said at least a bathymetric sector comprises at least a second sector, and in which the bathymetric map is obtained from measurements of first elevation angles of first backscattered signals emanating from acoustic pulses emitted in said first sector.
[0003]
3. Sonar according to claim 2, comprising an array (11) of transducers comprising a plurality of transducers distributed along a second axis (Z2) perpendicular to the first axis (X1), said transducers forming the array of transducers being dimensioned and configured so that their receiving lobes cover the first sector (S1) but said at least one second sector (S2) is located at least partially outside their receiving lobes, the first backscattered signals being acquired by means of the transducer array (11) .
[0004]
The synthetic antenna sonar according to claim 3, wherein the receiving physical antenna (3) comprises a first elementary physical antenna (5) formed of first transducers (T5) sized and configured so that their receiving lobes cover the first sector (S1) but such that said at least one second sector (S2) is at least partially outside their receiving lobes, wherein the sonar (1) comprises a second elementary physical antenna (6) formed of second transducers (T6) dimensioned and configured so that their receiving lobes cover the first and second sectors (S1, S2), and wherein the processing device (4) is configured to form, when forming the pathways of synthetic antenna, the channels of a first synthetic antenna from measurements of first backscattered signals from the first sector (S1), acquired by means of the first ant elementary (5) and channels of a second synthetic antenna from measurements of second backscattered signals from pulses transmitted in said second sector (S2, S3), acquired by means of the second elementary antenna (6).
[0005]
5. synthetic antenna sonar according to the preceding claim, wherein the array (11) of transducers is formed by the first antenna element (5) and another antenna (12) identical to the first antenna element (5) and superimposed on the first elementary physical antenna (5) along the second axis (Z2). 10
[0006]
6. A synthetic antenna sonar according to claim 1, wherein the bathymetric map is stored in a sonar memory before imaging the area observed.
[0007]
7. A sonar system comprising the sonar (1) according to any one of the preceding claims, and a carrier (PO), the sonar (1) being installed on the carrier (PO).
[0008]
8. Method of forming synthetic sonar antenna channels on sonar recurrences, the sonar (1) being intended to move along a first axis (X1), the sonar (1) comprising a device transmission (2) configured to transmit, at each recurrence, at least one acoustic pulse to an area observed in a sectored set comprising at least one sector, the sonar (1) comprising a first receiving physical antenna (3) extending according to the first axis (X1) making it possible to acquire backscattered signal measurements from said at least one pulse and a processing device (4) configured to form, on R recurrences, for each sector of the sectorized set, signaling channels; synthetic antenna from measurements of signals backscattered by the observed area from acoustic pulses emitted in said sector, the sonar (1) comprising at least one gyrometer, the method comprising a step (120, 121, 122) of formation, during which, for each sector on R recurrences, synthetic antenna paths are formed from measurements of signals backscattered by the observed zone originating from acoustic pulses emitted in said sector, in which, the variations of the movement of the first receiving antenna during the formation of the synthetic antenna channels of said sectorized assembly by performing an intercorrelated autocalibration of the successive recurrences, by using measurements of rotation of the first reception antenna (3) obtained with said minus one gyrometer and using backscattered signal angle estimates to determine image planes of the backscattered signals and to project said rotational measurements on said image planes, the projections obtained being used to perform the autocalibration, and when which during the formation of synthetic antenna channels of at least 10 a sector of the sectorized whole, called bathymetric sector, we use estimates of elevation angles of backscattered signals obtained from a bathymetric map comprising the three-dimensional position of a plurality of points of the observed zone. ts
[0009]
9. The synthetic antenna path forming method according to claim 8, wherein the transmitting device (2) is configured to emit, at each recurrence, acoustic pulses discernable to an observed zone, in sectors (S1, S2, S3) each comprising a first sector (S1) and at least a second sector (S2, S3), according to a first sighting axis (v1) and a second sighting axis (v2, v3) respectively having different bearing angles, wherein said at least one bathymetric area comprises at least a second sector, and wherein the bathymetric map is obtained from measurements of first site angles of first backscattered signals derived from acoustic pulses emitted in said first sector (S1).
[0010]
10, A method of forming synthetic antenna paths according to claim 9, wherein the sonar comprising a transducer array (11) comprising a plurality of elementary transducers distributed along a second axis (Z2) perpendicular to the first axis (X1), said transducers forming the array of transducers being dimensioned and configured so that their receiving lobes cover the first sector (S1) but said at least one second sector (S2) is located at least partially outside their reception lobes, the first backscattered signals being acquired at the medium array (11) of transducers, the method comprising, for each recurrence, a step (108) of measuring first elevation angles of first signals backscattered by means of the transducer array (11), a step (110) of calculating first angle of elevation estimates, of transposing measurements of the first angles of elevation in a r Terrestrial differential, the method comprising a step of producing (111) the bathymetric map from the estimates of the first elevation angles, the bathymetric map comprising three-dimensional coordinates, in the terrestrial reference, of probe points having backscattered the first backscattered signals .
[0011]
11. Method according to the preceding claim, comprising a step (112) for estimating the elevation angles of the backscattered signals from pulses emitted in said bathymetric sector from the bathymetric chart, comprising for each of the backscattered signals, a step ( 112a) for calculating the position of a point Mp of the bathymetric map closest to a portion of a circle Cp obtained by rotation about the first axis (X1) of a point B located on the other axis of aiming (v2) at a distance from the antenna corresponding to the distance separating the antenna from a probe point having generated the backscattered signal, a step (112b) of calculating a first point of intersection Ip between the bathymetric map and the circle portion Cp from the nearest point Mp, and a first step (112c) of calculation, in the terrestrial frame, of the elevation angle of the intersection point (112c).
[0012]
12. Method according to the preceding claim, wherein the point of intersection Ip is the point of intersection between a horizontal plane, in the terrestrial reference, passing through the nearest point Mp, and the circle portion Cp. 30
[0013]
13. The method of claim 11, comprising a second step of calculating a second intersection point Ip between the bathymetric map and the circle portion Cp from the nearest point Mp and other points of the bathymetric map. and if a second intersection point is obtained, a second step (112c) for calculating the elevation angle of the second intersection point (112c). 301 86 1 1 36
[0014]
The method according to any of claims 8 to 13, wherein the receiving physical antenna (3) comprises a first elementary physical antenna (5) formed of first transducers (T5) dimensioned and configured so that their lobes the at least one second sector (S2) is at least partially outside their receiving lobes, the channel forming step (120) of forming channels of a first synthetic antenna from measurements of backscattered signals from pulses transmitted in said first sector (S1) acquired by means of the first elemental antenna (5), in which the estimates of backscattered signal site angles used for determining image planes of the backscattered signals and for projecting said rotational measurements on said image planes are estimates of first sidelights of the first backscattered signals, the first backscattered signals being derived from pulses emitted in said first sector, the estimates of the first angles of view being transpositions of the measurements of the first angles of elevation in the terrestrial reference frame. 20

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同族专利:

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公开号 | 公开日

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WO2015136089A1|2015-09-17|

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JP2017508162A|2017-03-23|

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US20170059706A1|2017-03-02|

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FR3018611B1|2016-02-26|

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AU2015228768A1|2016-09-29|

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EP3117237A1|2017-01-18|

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AU2015228768B2|2019-02-07|

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JP6655022B2|2020-02-26|

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US11112499B2|2021-09-07|

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EP3117237B1|2019-10-30|

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SG11201607442SA|2016-10-28|

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CA2943759A1|2015-09-17|

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法律状态:
2015-03-09| PLFP| Fee payment|Year of fee payment: 2 |

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2016-02-23| PLFP| Fee payment|Year of fee payment: 3 |

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2017-02-27| PLFP| Fee payment|Year of fee payment: 4 |

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2018-02-27| PLFP| Fee payment|Year of fee payment: 5 |

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2020-02-27| PLFP| Fee payment|Year of fee payment: 7 |

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2021-02-25| PLFP| Fee payment|Year of fee payment: 8 |

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2022-02-21| PLFP| Fee payment|Year of fee payment: 9 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1400614A|FR3018611B1|2014-03-14|2014-03-14|SYNTHETIC ANTENNA SONAR AND METHOD FOR FORMING SYNTHETIC ANTENNA PATHWAYS|FR1400614A| FR3018611B1|2014-03-14|2014-03-14|SYNTHETIC ANTENNA SONAR AND METHOD FOR FORMING SYNTHETIC ANTENNA PATHWAYS|

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JP2016557020A| JP6655022B2|2014-03-14|2015-03-13|Synthetic antenna sonar and method for forming a synthetic antenna beam|

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EP15709690.0A| EP3117237B1|2014-03-14|2015-03-13|Synthetic antenna sonar and method for forming synthetic antenna channels|

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AU2015228768A| AU2015228768B2|2014-03-14|2015-03-13|Synthetic antenna sonar and method for forming synthetic antenna channels|

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PCT/EP2015/055334| WO2015136089A1|2014-03-14|2015-03-13|Synthetic antenna sonar and method for forming synthetic antenna channels|

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CA2943759A| CA2943759A1|2014-03-14|2015-03-13|Synthetic antenna sonar and method for forming synthetic antenna beams|

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US15/123,406| US11112499B2|2014-03-14|2015-03-13|Synthetic antenna sonar and method for forming synthetic antenna beams|

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SG11201607442SA| SG11201607442SA|2014-03-14|2015-03-13|Synthetic antenna sonar and method for forming synthetic antenna beams|