Method for calibrating an acoustic antenna

The invention claimed is: 1. A method for calibrating an acoustic antenna, the acoustic antenna comprising a plurality of transducers, each transducer being configured to generate an electrical signal when detecting an acoustic wave, the antenna comprising elementary transducers distributed over an antenna row or an antenna plane, about a reference transducer, the antenna defining a main axis, passing through the reference transducer, and perpendicular to the antenna row or antenna plane, the method comprising: a) placing a calibration source in at least one position with respect to the antenna, the calibration source being configured to transmit a calibration acoustic wave that propagates to the antenna; b) measuring signals generated by all or some of the elementary transducers, including the reference transducer, in response to the calibration acoustic wave; c) on the basis of the signals measured in step b), determining a temporal phase shift of the signal respectively generated by each elementary transducer, each temporal phase shift being defined with respect to a reference signal measured by the reference transducer; d) reiterating a) to c), so that, in at least one iteration, the position of the calibration source is considered to be centered on the main axis; the method further comprising estimating an intrinsic phase shift, of each elementary transducer with respect to the reference transducer, the estimating of the intrinsic phase shift comprising: e) concatenating temporal phase shifts determined in each step c), with respect to each elementary transducer, so as to form a vector of phase shifts, said vector of phase shifts being stored in a processing unit; f) taking into account a change-of-basis matrix, said change-of-basis matrix being stored in the processing unit; g) on the basis of the change-of-basis matrix and of the vector of phase shifts, estimating the intrinsic phase shift of each elementary transducer with respect to the reference transducer. 2. The method as claimed in claim 1 , wherein the antenna extends along a longitudinal axis, and wherein at least one iteration of steps a) to c) is implemented with the calibration source placed in a position off the main axis, such that the acoustic wave transmitted by the calibration source propagates to the reference transducer in such a way as to make a first angle to the longitudinal axis, wherein: in f), the change-of-basis matrix contains the respective distances, along the longitudinal axis, between the reference transducer and each elementary transducer; g) comprises estimating the first angle. 3. The method of claim 2 , wherein, in the change-of-basis matrix, the distances between the reference transducer and each elementary transducer, along the longitudinal axis, are normalized by a propagation speed of the acoustic wave. 4. The method of claim 2 , wherein the antenna also extends along a lateral axis that is secant to the longitudinal axis, such that the acoustic wave transmitted by the calibration source propagates to the reference transducer in such a way as to make a second angle to the lateral axis, and wherein: in f), the change-of-basis matrix contains the respective distances, along the lateral axis, between the reference transducer and each elementary transducer; g) comprises estimating the second angle. 5. The method of claim 4 , wherein, in the change-of-basis matrix, the distances between the reference transducer and each elementary transducer, along the lateral axis, are normalized by a propagation speed of the acoustic wave. 6. The method of claim 1 , wherein: the iterations of a) to c) are repeated, the calibration source being centered with respect to the main axis; the change-of-basis matrix contains a concatenation of a number of identity matrices equal to the number of iterations performed, the size of each identity matrix corresponding to the number of elementary transducers for which it is desired to determine the phase shift. 7. The method of claim 1 , wherein the iterations of a) to c) are repeated for at least one given position of the calibration source. 8. The method of claim 1 , comprising, for all or some of the elementary transducers: h) transmitting an acoustic wave to the antenna, and of comparing the signals respectively generated by each elementary transducer and by the reference transducer in response to the transmitted acoustic wave, so as to assign a gain to each elementary transducer on the basis of the comparison. 9. The method of claim 8 , wherein the comparison is a ratio between the respective integrals of the absolute values of the signals respectively generated by each elementary transducer and by the reference transducer. 10. The method of claim 1 , wherein steps e) to g) are implemented by a the processing unit connected to the transducers of the antenna. 11. The method of claim 1 , wherein a transducer of the antenna transmits an acoustic wave to a reflector placed facing the antenna, so that the acoustic wave reflected by the reflector foil is the calibration acoustic wave. 12. An acoustic antenna, comprising a plurality of transducers, each transducer being configured to generate an electrical signal under the effect of a detection of an acoustic wave, the antenna comprising elementary transducers distributed over an antenna row or an antenna plane, about a reference transducer, the antenna defining a main axis, passing through the reference transducer, and perpendicular to the antenna row or antenna plane, the antenna comprising a processing unit, configured to implement steps c) to g) of a method as claimed in claim 1 , on the basis of signals generated by all or some of the elementary transducers in response to a calibration acoustic wave transmitted by a calibration acoustic source placed facing the antenna. 13. The method of claim 1 , wherein said change-of-basis matrix forms a mathematical link between the vector of phase shifts and a vector containing intrinsic phase shift of each elementary transducer with respect to the reference transducer.