Ultra wide bandwidth piezoelectric transducer arrays

What is claimed is: 1. A piezoelectric micromachined ultrasonic transducer (pMUT) array, comprising: a plurality of drive/sense electrode rails disposed over an area of a substrate and electrically addressable independently; and a plurality of piezoelectric transducer element populations, wherein drive/sense electrodes within an element population are coupled to one of the drive/sense electrode rails, wherein electromechanical coupling between transducer elements of different transducer element populations is less than electromechanical coupling between transducer elements of a same element population, and wherein each transducer element population is to provide a plurality of separate but overlapping frequency responses; wherein the electromechanical coupling between transducer elements of a same element population is sufficient to induce at least one degenerate mode, the at least one degenerate mode having a degenerate resonant frequency split from a natural resonant frequency of an individual piezoelectric transducer element in the element population, wherein at least one of a distance, the elastic modulus of a material, or a cross-sectional coupling area of a first region between transducer elements of a same element population is different than a corresponding one of a second region between transducer elements of a different element populations, wherein two or more of the distance, the elastic modulus, or the cross-sectional coupling area are different between the first and second regions. 2. The pMUT array of claim 1 , wherein the plurality of frequency responses comprises more than two distinct frequency peaks. 3. The pMUT array of claim 1 , wherein the electromechanical coupling between transducer elements of a same element population is sufficient to induce a plurality of degenerate modes, the plurality of degenerate modes having degenerate resonant frequencies split from each other. 4. The pMUT array of claim 1 , wherein an interconnecting material and cross-sectional coupling areas are the same in the first and second regions. 5. The pMUT array of claim 1 , wherein each piezoelectric transducer element population is disposed over a length of the substrate that is at least five times larger than a width of the substrate occupied by the element population with piezoelectric membranes arranged in single file with centers aligned along a straight line. 6. The pMUT array of claim 1 , wherein each piezoelectric transducer element population is disposed over a length of the substrate that is at least five times larger than a width of the substrate occupied by the element population with the plurality of piezoelectric transducer elements arranged in a close packed configuration where at least two adjacent piezoelectric membranes overlap along the length of the substrate and are offset from single file along width of the substrate. 7. The pMUT array of claim 1 , wherein each piezoelectric transducer element population comprises a plurality of piezoelectric membranes of differing membrane size to provide a plurality of separate resonant frequencies. 8. The pMUT array of claim 7 , wherein each piezoelectric transducer element population comprises more than one piezoelectric transducer element of each membrane size. 9. The pMUT array of claim 8 , wherein each piezoelectric transducer element population is disposed over a length of the substrate that is at least five times larger than a width of the substrate occupied by the element population; and wherein each piezoelectric transducer element population further comprises a plurality of transducer element subgroups, each subgroup comprising one piezoelectric transducer element of each nominal membrane size; and wherein the element population has transducer elements of a same size spaced apart by at least one intervening element of a different size and no more than a length of the substrate occupied by one element subgroup. 10. The pMUT array of claim 7 , wherein piezoelectric membranes of each piezoelectric transducer element population are in single file along a first dimension. 11. The pMUT array of claim 7 , wherein piezoelectric membranes of each piezoelectric transducer element population are in a close packed configuration having at least two adjacent piezoelectric membranes overlapping along the length of the substrate and offset from single file along width of the substrate. 12. The pMUT array of claim 7 , wherein the plurality of drive/sense electrode rails forms a two-dimensional array of drive/sense electrode rails along a first and second dimension of the substrate; wherein each of the plurality of transducer element populations comprises a same number of transducer elements, and each of the plurality of transducer element populations has a same relative spatial arrangement of transducer elements, and wherein a first transducer element population coupled to a first drive/sense electrode rail has the relative spatial arrangement of transducer elements at a first orientation, and wherein a second transducer element population coupled to second drive/sense electrode rail has the relative spatial arrangement of transducer elements at a second orientation. 13. The pMUT array of claim 1 , wherein transducer elements within each transducer element population is closely packed and wherein adjacent transducer element populations are less closely packed than those within an element population. 14. The pMUT array of claim 1 , wherein at least one piezoelectric transducer element in each of the element populations comprises a piezoelectric membrane having an elliptical geometry with at least first and second semi-principal axes of differing length to provide the plurality of separate resonant frequencies. 15. The pMUT array of claim 14 , wherein the elliptical geometry comprises an ellipsoid having a first, second and third semi-principal axes, wherein the first and second semi-principal axes are in the plane of the substrate. 16. The pMUT array of claim 14 , wherein the first and second semi-principal axes for membranes within one of the piezoelectric transducer element populations are in a plane that is parallel with the area of the substrate. 17. The pMUT array of claim 16 , wherein the shorter of the first and second semi-principal axes is aligned in a direction parallel to a longest length of the substrate occupied by one of the element populations. 18. The pMUT array of claim 16 , wherein first and second semi-principal axes of a first element population have a first orientation, and wherein a first and second semi-principal axes of a second element population adjacent to the first population have a second orientation, orthogonal to the first orientation. 19. The pMUT array of claim 18 , wherein the first and second semi-principal axes are oriented at 45° relative to a longest length of the substrate occupied by one of the element populations. 20. An apparatus for generating and sensing pressure waves in a medium, the apparatus comprising: the pMUT array of claim 1 ; generating means coupled to the pMUT array to apply an electrical drive signal on at least one drive/sense electrode; receiving means coupled to the pMUT array to receive an electrical response signal from at least one drive/sense electrode; and signal processing means coupled to the receiving means to process electrical response signals received from the plurality of the drive/sense electrodes. 21. The apparatus of claim 20 , wherein the generating means is to apply an electrical d