Implantable wireless acoustic stimulators with high energy conversion efficiencies

We claim: 1 . An implantable receiver-stimulator, comprising: an enclosure extending along a longitudinal axis and having an inner surface and an outer surface, wherein the enclosure has a first end portion and a second end portion opposite to the first end portion along the longitudinal axis, a cap coupled to the first end portion and having an inner surface and outer surface; a plurality of first acoustic transducers mounted to the inner surface of the enclosure and distributed circumferentially about the inner surface of the enclosure relative to the longitudinal axis, wherein individual ones of the first acoustic transducer (a) have a base portion mounted to the inner surface of the enclosure defining an aperture for receiving acoustic power from an acoustic field along an acoustic axis extending orthogonal to the longitudinal axis and (b) are configured to convert the received acoustic power to electrical power; a plurality of second acoustic transducers mounted to the inner surface of the cap, wherein individual ones of the second acoustic transducers (a) have a base portion mounted to the inner surface of the cap and defining an aperture for receiving the acoustic power from the acoustic field along an acoustic axis extending parallel to the longitudinal axis and (b) are configured to convert the received acoustic power to electrical power; and at least one electrode configured to receive the electrical power from the first acoustic transducer and the second acoustic transducers and deliver at least a portion of the electrical power to tissue. 2 . The implantable receiver-stimulator of claim 1 wherein the cap is a first, cap, and further comprising: a second cap coupled to the second end portion and having an inner surface and outer surface; and a plurality of third acoustic transducers mounted to the inner surface of the second cap, wherein individual ones of the third acoustic transducers (a) have a base portion mounted to the inner surface of the second cap and defining an aperture for receiving the acoustic power from the acoustic field along an acoustic axis extending parallel to the longitudinal axis and (b) are configured to convert the received acoustic power to electrical power. 3 . An implantable receiver-stimulator, comprising: an enclosure extending along a longitudinal axis and having an inner surface and an outer surface; a plurality of acoustic transducers mounted to the inner surface and distributed circumferentially about the inner surface relative to the longitudinal axis, wherein individual ones of the acoustic transducers (a) have a base portion mounted to the inner surface of the enclosure and defining an aperture for receiving acoustic power from an acoustic field along an acoustic axis extending orthogonal to the longitudinal axis and (b) are configured to convert the received acoustic power to electrical power, and wherein individual ones of the acoustic transducers are non-isotropic; and at least one electrode configured to receive the electrical power from the acoustic transducers and deliver at least a portion of the electrical power to tissue. 4 . The implantable receiver-stimulator of claim 3 wherein the enclosure is hermetically sealed. 5 . The implantable receiver-stimulator of claim 3 wherein the acoustic transducers are mounted to the inner surface in a plurality of rows extending parallel to the longitudinal axis, and wherein the rows are distributed circumferentially about the longitudinal axis. 6 . The implantable receiver-stimulator of claim 5 wherein the acoustic transducers are arranged in more than four of the rows. 7 . The implantable receiver-stimulator of claim 5 wherein the rows are distributed symmetrically about the longitudinal axis. 8 . The implantable receiver-stimulator of claim 3 wherein individual ones of the acoustic transducers are cuboid shaped. 9 . The implantable receiver-stimulator of claim 3 wherein individual ones of the acoustic transducers comprise a polycrystalline ceramic piezoelectric material or a single crystal piezoelectric material. 10 . The implantable receiver-stimulator of claim 3 wherein the tissue is cardiac tissue of a human. 11 . An implantable receiver-stimulator, comprising: enclosure extending along a longitudinal axis and having an inner surface and an outer surface; a plurality of acoustic transducers mounted to the inner surface and distributed circumferentially about the inner surface relative to the longitudinal axis, wherein individual ones of the acoustic transducers (a) have a base portion mounted to the inner surface of the enclosure and defining an aperture for receiving acoustic power from an acoustic field along an acoustic axis extending orthogonal to the longitudinal axis and (b) are configured to convert the received acoustic power to electrical power; a plurality of rectifiers mounted to the inner surface and distributed circumferentially about the inner surface relative to the longitudinal axis, wherein individual ones of the rectifiers are electrically coupled to a corresponding one of the acoustic transducers and configured to receive and rectify the electrical power therefrom; and at least one electrode configured to receive the electrical power from the rectifiers and deliver at least a portion of the electrical power to tissue. 12 . An implantable receiver-stimulator, comprising: an enclosure extending along a longitudinal axis and having an inner surface and an outer surface, wherein the enclosure includes a plurality of regions of reduced thickness between the inner surface and the outer surface, and wherein the regions of reduced thickness are distributed circumferentially about the enclosure relative to the longitudinal axis; a plurality of acoustic transducers mounted to the inner surface, wherein individual ones of the acoustic transducers (a) have a base mounted to the inner surface of the enclosure adjacent to a corresponding one of the regions of reduced thickness and configured to receive acoustic power from an acoustic field through the region of reduced thickness and (b) are configured to convert the received acoustic power to electrical power, wherein individual ones of the acoustic transducers are non-isotropic; and at least one electrode configured to receive the electrical power from the acoustic transducers and deliver at east a portion of the electrical power to tissue. 13 . The implantable receiver-stimulator of claim 12 wherein individual ones of the acoustic transducers are configured to receive the acoustic power through the region of reduced thickness along an acoustic axis extending orthogonal to the longitudinal axis. 14 . The implantable receiver-stimulator of claim 12 wherein the enclosure is hermetically sealed. 15 . The implantable receiver-stimulator of claim 12 wherein individual ones of the acoustic transducers have a first isotropy for receiving the acoustic power, and wherein the acoustic transducers are distributed circumferentially about the inner surface relative to the longitudinal axis such that the acoustic transducers collectively have a second isotropy, greater than the first isotropy, for receiving the acoustic power. 16 . The implantable receiver-stimulator of claim 12 wherein the acoustic transducers are mounted to the inner surface in a plurality of rows extending parallel to the longitudinal axis, and wherein the rows are distributed circumferentially about the longitudinal axis. 17 . The implantable receiver-stimulator of claim 12 wherein individual ones of the acoustic