A method of manufacturing a high aspect ratio structure includes: a hole forming step of forming a plurality of holes in at least one principal surface of a substrate; a resist forming step of forming a first area with a resist layer and a second area without the resist layer on the principal surface provided with the plurality of holes after the hole forming step ends; and a concave portion forming step of immersing the substrate into an etching solution to form a concave portion in the substrate corresponding to the second area.

A method of fabricating an acoustic transducer comprising: fabricating a substrate; depositing a bottom electrode on the substrate; depositing an active layer on the bottom electrode; depositing a top electrode on the active layer; wherein at least one electrode is patterned to form at least two active elements; and, wherein a ratio of a thickness coupling coefficient k.sub.t to an effective lateral coupling coefficient k.sub.31,eff of the active layer is 1.3 or greater.

In respective methods for manufacturing a high aspect ratio structure and an ultrasonic probe, a plurality of holes extending in a direction crossing a main surface of a substrate are formed, a plurality of first regions and second regions excluding the first regions from the main surface are periodically defined, and partition walls between the plurality of holes formed in the substrate corresponding to the first regions are removed by etching so that part of each of the partition walls within a predetermined range excluding a bottom portion is left. A high aspect ratio structure and an X-ray imaging apparatus include, over a side wall, a porous member including a plurality of holes extending in a direction crossing a grating surface within a predetermined range excluding a bottom portion in each of a plurality of recesses in a grating.

Provided are a haptic feedback fiber body, a haptic feedback fabric, and a wearable device. The haptic feedback fiber body can include a core fiber having a first electrode to surround the outer surface thereof; and a vibrating fiber, provided so as to intermittently contact the outer surface of the core fiber, including a second electrode on the inner surface thereof, wherein a piezoelectric polymer is provided on the outer surface of the first electrode or on the inner surface of the second electrode to generate fretting vibrations when the polymer is in close contact with the first electrode or the second electrode on which the piezoelectric polymer is disposed opposite to each other.

An ultrasonic sensing device includes a circuit board, a piezoelectric material layer on the circuit board, a first electrode, and a second electrode on the circuit board. The circuit board is configured to dispose a circuit. The first electrode is formed on a surface of the piezoelectric material layer away from the circuit board. The piezoelectric material layer is between the first electrode and the second electrode; the first electrode has a thickness in a range from 0.005 m to 1 m.

A method includes determining, for a piezoelectric cantilever-type transducer of a distributed mode loudspeaker adapted to cause vibration of a load, a subset of frequencies from a range of frequencies at which to output vibrations, in which the transducer includes two or more electrode pairs positioned along a length of the transducer and each electrode pair including a first electrode on a first side of a piezoelectric layer of the transducer and a second electrode on a second side of the piezoelectric layer of the transducer that is opposite to the first side; selecting, for the subset of frequencies, a respective input voltage for each of the two or more electrode pairs based on a relative position of each pair on the transducer; and applying the respective input voltage to each of the two or more electrode pairs to cause the transducer to generate a vibrational force.

A transducer array for an ultrasound probe is provided. The transducer array includes a plurality of transducer elements. Each of the transducer elements have an acoustic stack configured to generate ultrasound signals. The transducer array includes a front layer having a base and a transmission surface. The front layer is mounted to the acoustic stacks of the plurality or transducer elements. The transmission surface includes a linear incline. The transmission surface is configured to emit the ultrasound signals.

Ultrasound devices and systems are disclosed in which cooling of an active acoustic element of an ultrasound transducer is achieved via an electrically conductive member that extends beyond a proximal side of the active acoustic element to contact a heat exchanger. The electrically conductive member delivers electrical driving signals to the active acoustic element while conducting heat to the heat exchanger. A region of the proximal surface of the active acoustic element that is free from contact with the electrically conductive member may also absent from contact with a liquid or a solid, thereby facilitating reflection of ultrasound energy. The heat exchanger may include an electrically insulating fluid that contacts the electrically conductive member to remove the heat conducted through the electrically conductive member. The active acoustic element may be a multilayer lateral mode element, and the electrically conductive member may form an electrode of the lateral mode element.

An ultrasonic transducer and an ultrasonic probe including the same are provided. The ultrasonic transducer includes a piezoelectric layer configured to convert an electric signal and an ultrasound into each other, and a dematching layer having a uniform thickness, the dematching layer being arranged on a partial region of the piezoelectric layer and configured to reflect the second ultrasound wave that is incident on the dematching layer.

An ultrasound transducer with at least one piezoelectric element configured to convert received acoustic signals into an electric potential, a shield connectable to ground and overlying the at least one piezoelectric element through which the acoustic signals pass, before being received by the at least one piezoelectric element, the shield having acoustic conductivity and electrical attenuation characteristics that enable the acoustic signals to propagate therethrough while reducing a 100 volt per centimeter electric field to below a threshold level so that the piezoelectric element is exposed to a threshold electrical potential at least less than or equal to 10 V, and a housing accommodating the at least one piezoelectric element and shield.