Sensors and methods for generating spatially encoded acoustic fields by sound-emitting apertures with spatially varying frequency and bandwidth

We claim: 1 . An acoustic transducer for generating and/or receiving a spatially structured acoustic field, comprising: a total aperture which generates and/or receives said acoustic field, wherein said total aperture comprises a plurality of sub-apertures, wherein each of said sub-apertures is arranged to receive and/or generate ultrasound having a specific frequency spectrum, wherein the specific frequency spectra of at least two of said sub-apertures differ from each other, and wherein all sub-apertures of said total aperture are connected to a same electronic drive channel. 2 . The acoustic transducer of claim 1 , wherein said plurality of sub-apertures are distributed substantially in a plane perpendicular to a direction of propagation of the acoustic field. 3 . The acoustic transducer of claim 1 , wherein the plurality of sub-apertures have, at least in part, different diameters. 4 . The acoustic transducer according to claim 1 , wherein said electrical drive channel is arranged to output an alternating signal having a predetermined frequency spectrum to said sub-apertures, said alternating signal exciting at least one movable element of each sub-aperture to vibrate. 5 . The acoustic transducer according to claim 1 , wherein said total aperture is formed by a piezoelectric element, and wherein the sub-apertures are formed by regions of the piezoelectric element having different thickness. 6 . The acoustic transducer of claim 1 , wherein the total aperture is formed by a piezoelectric or capacitive micromechanical sound transducer, and wherein the plurality of sub-apertures are formed by a plurality of membranes of the acoustic transducer, and wherein the membranes at least partially have different diameters. 7 . The acoustic transducer of claim 1 , wherein the total aperture is formed by a high-bandwidth single acoustic transducer together with a passive attachment module for the single acoustic transducer, the passive attachment module comprising regions of different frequency-dependent attenuation forming the plurality of sub-apertures. 8 . The acoustic transducer of claim 1 , wherein the sub-apertures are formed by single acoustic transducers of high bandwidth, wherein each of the single acoustic transducers is preceded by an electronic filter which limits the bandwidth of the single acoustic transducer to a specific frequency spectrum. 9 . The acoustic transducer of claim 1 , wherein the total aperture is formed by a passive base body having recesses for a plurality of individual acoustic transducers, the plurality of individual acoustic transducers forming the plurality of sub-apertures. 10 . A transducer device comprising a plurality of periodically arranged acoustic transducers according to claim 1 , each transducer having and being connected to a separate electronic drive channel. 11 . A method of manufacturing an acoustic transducer according to claim 1 , comprising: determining a desired spatial acoustic field distribution of a total aperture; obtaining, from the desired acoustic field distribution, parameters of a plurality of sub-apertures that form the total aperture, wherein obtaining said parameters comprises at least one of: an analytical calculation of the parameters, a numerical calculation of the parameters, and a simulation method for the parameters. 12 . The method of claim 11 , wherein obtaining the parameters of said sub-apertures comprises: calculating partial acoustic field distributions each having a specific frequency spectrum such that a superposition of all partial acoustic field distributions results in the desired spatial acoustic field distribution, and obtaining parameters of the sub-apertures such that each sub-aperture is designed to produce one of the partial acoustic field distributions. 13 . The method of claim 11 , wherein said parameters of a sub-aperture comprise at least one of the following: dimensions of a sub-aperture, a geometric shape of a sub-aperture, a thickness of a movable element of a sub-aperture, and a relative arrangement of a sub-aperture within the total aperture. 14 . A method of decoding a spatially structured acoustic field comprising: detecting an ultrasonic signal comprising reflected signals of an irradiated acoustic field, the irradiated acoustic field having a predetermined spatial structure, and calculating, on the basis of said detected signal and said predetermined spatial structure of the irradiated acoustic field, a spatial distribution of reflecting elements which generate the reflected signals, wherein said ultrasonic signal is detected using a transducer according to claim 1 , and wherein said ultrasonic signal is present as an output signal of the one electrical drive channel of the transducer. 15 . The method of claim 14 , further comprising: displaying a two-dimensional or three-dimensional image from said calculated spatial distribution of reflecting elements.