An array of micromachined ultrasonic transducers (MUTs). The array has first and second rows, the MUTs in the first row being equally spaced by a horizontal pitch in a horizontal direction, the MUTs in the second row being equally spaced by the horizontal pitch in the horizontal direction. The MUTs in the second row are shifted along the horizontal direction by a first horizontal distance relative to the MUTs in the first row and shifted along a vertical direction by a first vertical distance relative to the MUTs in the first row. The first horizontal distance is greater than zero and less than the horizontal pitch. The first vertical distance ranges from one tenth of a horizontal width of a MUT to a half of a vertical height of a MUT.

A piezoelectric micromachined ultrasonic transducer (PMUT) device includes a substrate having an opening therethrough and a membrane attached to the substrate over the opening. A portion of the membrane that overlies the opening is divided into a plurality of cantilevers that are mechanically coupled so that the cantilevers resonate at a common frequency.

A bender bar acoustic transducer capable of exciting at least three resonance modes is provided. The provided bender bar acoustic transducer may be capable of exciting a second resonance mode by configuring a first portion of a piezoelectric element to contract while a second portion of the piezoelectric element expands when voltage is applied to electrodes coupled to the piezoelectric element. The bender bar acoustic transducer may be further configured such that the first portion and the second portion of the piezoelectric element both contract and/or expand to excite a first resonance mode. The bender bar acoustic transducer may be used in downhole and well logging applications.

An acoustic transducer, such as a bender bar, having ferroelectric actuation elements that are designed to optimize a predetermined deflection mode shape. The acoustic transducers may include one or more rounded modally shaped actuation elements or weighted actuation elements. Modal shaping of the actuation elements allows for specific targeting of modes which most efficiently radiate acoustic energy.

An ultrasonic sensor including a case having a bottom portion, and a piezoelectric element that is bonded to an inner surface of the bottom portion and performs bending vibration together with the bottom portion. The piezoelectric element includes a piezoelectric layer having a transmission region and a reception region, a common electrode, a transmission electrode opposing the common electrode with the transmission region interposed therebetween, and a reception electrode opposing the common electrode with the reception region interposed therebetween. The transmission region and the reception region are formed at positions adjacent to each other.

An ultrasonic transducer that can include a driver side and a bias voltage side. A higher voltage source can be electrically connected to the bias voltage side through a first resistor. A lower voltage source can be electrically connected to the driver side of through a second resistor. A field effect transistor or other suitable switch can be included, having a source, a gate and a drain. The source can be electrically connected to ground and the gate can be electrically connected to a control signal source. The drain can be electrically connected to the lower voltage source through a second resistor and be electrically connected to the driver side of the ultrasonic transducer. The gate can be electrically connected to a signal source through a third resistor.

A haptic actuator comprising a first actuation component and a second actuation component is presented. The first actuation component comprises a first layer of actuatable material and electrodes on opposite sides of the first layer, wherein the actuatable material is configured to deform upon any electrical signal being applied to at least one of the electrodes. The haptic actuator further comprises a second layer separated from the first actuation component by one or more spacers. The second actuation component comprises a magnetized material and one or more electromagnets. Either the magnetized material or the one or more electromagnets are disposed on the first actuation component, and relative movement between the magnetized material and the one or more electromagnets is generated upon any electrical signal being applied to the one or more electromagnets, wherein the relative movement causes vibration of the first actuation component.

A method for determining mechanical properties of tissue in an individual includes attaching a stretchable and/or flexible ultrasound imaging device to the individual. The imaging device includes at least a one-dimensional array of transducer elements that transmit ultrasound waves into the individual. A first series of ultrasound waves are received from the tissue in the individual before applying a strain to the tissue by compression and a second series of ultrasound waves are received from the tissue after applying the compression to the tissue. Data from the first and second series of ultrasound waves are compared to obtain displacement data of the tissue from which strain data representing strain applied to the tissue is obtainable. A 2D image representing a 2D modulus distribution within the tissue is generated using the displacement data. One or more mechanical properties of the tissue is identified based on the 2D modulus distribution.

An intraluminal sensing device may include an elongate member, a sensor, an acoustic matching layer, and a housing. The elongate member may be configured to be positioned within a body lumen of a patient. The sensor may be configured to obtain physiological data while positioned within the body lumen and may include a proximal surface and an opposite, distal surface. The acoustic matching layer may be disposed on the distal surface. The housing may be positioned at a distal portion of the elongate member and may terminate at a distal end. The housing may include a hollow interior with a planar surface, and the sensor may be positioned within the hollow interior such that the proximal surface of the sensor is disposed on the planar surface. A thickness of the acoustic matching layer may be defined by a distance between the distal surface and the distal end.

A sound generator includes a housing and a vibrator. The vibrator includes at least one piezoelectric element and has at least of a part thereof inside the housing. A contact portion on the at least one piezoelectric element is configured to transmit generated vibration to an object outside of the sound generator. The at least one piezoelectric element generates vibration in response to a signal from outside the vibrator, and causes the object to vibrate and generate a sound to emit from the object.