A device for transmitting and receiving acoustic waves is provided herein. In one or more examples, the device comprises: a polymer infill; a first set of piezoelectric components, wherein the first set of piezoelectric components comprises one or more piezoelectric components, disposed in a first annular area interstitially in the polymer infill, the first annular area defined by a first inner ring and a first outer ring; a second set of piezoelectric components, wherein the second set of piezoelectric components comprises one or more piezoelectric components, disposed in a second annular area interstitially in the polymer infill, the second annular area defined by a second inner ring and second outer ring; and wherein the rings are spaced apart from each other radially based on one or more Gaussian distributions.

An acoustic sensor is configured to provide accurate and robust measurement of bodily sounds under a variety of conditions, such as in noisy environments or in situations in which stress, strain, or movement may be imparted onto a sensor with respect to a patient. Embodiments of the sensor provide a conformable electrical shielding, as well as improved acoustic and mechanical coupling between the sensor and the measurement site.

An object of the present invention is to provide a cut sheet-like piezoelectric film which includes electrode layers on both surfaces of a piezoelectric layer and is capable of preventing a short circuit of the electrode layers. The object is achieved by providing a cut sheet-like piezoelectric film including a piezoelectric layer which contains piezoelectric particles in a matrix containing a polymer material, and electrode layers which are provided on both surfaces of the piezoelectric layer, in which a distance between the electrode layers at an end portion in a thickness direction is 40% or greater with respect to a thickness of the piezoelectric layer.

A piezoelectric band (10) includes: a base sheet (11) that has flexibility and is formed into a sheet shape; a piezoelectric sheet (20) that has flexibility and is formed into a sheet shape and placed over one side of the base sheet (11); and a cover sheet (12) that has flexibility and is formed into a sheet shape and placed over and in contact with one side of the piezoelectric sheet (20) that faces away from the base sheet (11). Upon reception of a drive signal, the piezoelectric sheet (20) vibrates at or above a frequency of 15 kHz. The cover sheet (12) has a plurality of holes (12a) passing therethrough from one side facing the piezoelectric sheet (20) to the other side, and the plurality of holes (12a) forms respectively air layers through which vibration of the piezoelectric sheet (20) propagates toward the other side.

A piezoelectric microelectromechanical system microphone comprises a support substrate, a membrane including a piezoelectric material attached to the support substrate and configured to deform and generate an electrical potential responsive to impingement of sound waves on the membrane, and a compliant anchor including a trench defined in the support substrate about a portion of a perimeter of the membrane to increase sensitivity of the piezoelectric microelectromechanical system microphone.

Aspects of acoustic transducers are described. One aspect is a microelectromechanical (MEMS) transducer comprising a substrate and multiple cantilevered beams. A first cantilevered beam comprises a first protrusion and a first piezoelectric structure, where the first piezoelectric structure comprises a first deflection end and a first fixed end, where the first fixed end is coupled to the substrate, and where the first deflection end is cantilevered away from the substrate. The first cantilevered beam is separated from a second cantilevered beam by a gap. The first protrusion is disposed at the first deflection end and increases a thickness of the first cantilevered beam along the gap at the first deflection end. A second protrusion of the second beam is disposed at a second deflection end and increases a thickness of the second cantilevered beam along the gap at the second deflection end.

Provided is a voice sensor comprising a piezoelectric material layer includes a substrate, a support layer, a metal layer, a piezoelectric material layer on the metal layer and an electrode on the piezoelectric material layer, and the substrate integrally supports a device layer of the voice sensor by exposing a part of a thin film including the piezoelectric material layer, the electrode and a polymer layer.

The present disclosure is of a bone conduction sound transmission device. The bone conduction sound transmission device comprises a laminated structure and a base structure. The laminated structure is formed by a vibration unit and an acoustic transducer unit. A base structure is configured to load the laminated structure, and at least one side of the laminated structure is physically connected to the base structure. The base structure vibrates based on an external vibration signal, and the vibration unit deforms in response to the vibration of the base structure; and the acoustic transducer unit generates an electrical signal based on the deformation of the vibration unit.

A piezoelectric, poly (γ-benzyl-α,L-glutamate) (“PBLG”) planar microphone, and method for construction thereof, are disclosed. The microphone includes at least a polyester film, a piezoelectric, hot pressed poly (γ-benzyl-α,L-glutamate) (“HPPBLG”) layer, and an aluminum coating for the HPPBLG layer. The coated HPPBLG layer is coupled to the polyester film.

A MEMS device and a method of manufacturing the same are provided. A semiconductor device includes a substrate; and a membrane over the substrate and configured to generate charges in response to an acoustic wave, the membrane being in a polygonal shape including vertices. The membrane includes a via pattern having first lines that partition the membrane into slices and extend to the vertices of the membrane such that the slices are separated from each other near an anchored region of the membrane and connected to each other around a central region. The via pattern further includes second lines extending from the anchored region of the membrane toward the central region of the membrane. Each of the second lines includes a length less than a length of each of the first lines.