The present disclosure relates to driver circuitry for driving a piezoelectric transducer. The circuitry comprises: output stage circuitry configured to receive an input signal and to drive the piezoelectric transducer to produce the output signal; variable voltage power supply circuitry configured to output a supply voltage for the charge drive output stage circuitry, wherein the supply voltage output by the variable voltage power supply circuitry varies based on the input signal; a supply capacitor for receiving the supply voltage output by the variable voltage power supply circuitry; a reservoir capacitor; and circuitry for transferring charge between the reservoir capacitor and the supply capacitor.

An imaging device includes a transducer that includes an array of piezoelectric elements formed on a substrate. Each piezoelectric element includes at least one membrane suspended from the substrate, at least one bottom electrode disposed on the membrane, at least one piezoelectric layer disposed on the bottom electrode, and at least one top electrode disposed on the at least one piezoelectric layer. Adjacent piezoelectric elements are configured to be isolated acoustically from each other. The device is utilized to measure flow or flow along with imaging anatomy.

An ultrasound transducer includes: a flexible board configured to receive and output an electrical signal through a signal line; a plurality of piezoelectric devices that are electrically connected to the board and are aligned in a row, each piezoelectric device being configured to transmit and receive an ultrasound wave; a plurality of leads extending the signal line and protruding from an end portion of the board, each lead being electrically connected to the piezoelectric device in a curved manner; and a plurality of sheets that are arranged to prevent the leads from being in contact with each other, each sheet being provided on the lead and having an insulation property.

The present disclosure relates to an ultrasonic device for real-time and nondestructive assessment of extracellular matrix stiffness, and the method of making and using the novel ultrasonic device.

Piezoelectric sensor controllers may facilitate detection and identification of various potential fault states with novel parameter measurements. In an illustrative embodiment of a piezoelectric-based sensor having a shorted-reverberation based resonant frequency measurement, the sensor includes a piezoelectric transducer that provides residual reverberation after being driven. The sensor further includes a controller that provides a low impedance path for the piezoelectric transducer during the residual reverberation and that measures current through the low impedance path to determine a resonant frequency of the piezoelectric transducer. In an illustrative embodiment of a sensing method having a shorted-reverberation based resonant frequency measurement, the method includes: driving a piezoelectric transducer that provides residual reverberation after being driven; providing a low impedance path for the piezoelectric transducer during the residual reverberation; and measuring current through the low impedance path to determine a resonant frequency of the piezoelectric transducer.

An ultrasonic vibration assisted machining device is applied to a cutting tool and includes a vibrating component and a spinning component. The vibrating component includes a main body including a first end surface, a second end surface and a central axis. The vibrating component is configured to receive electrical power and generate a vibration with a vibrating frequency in the central axis direction according to the electrical power. The spinning component includes a first surface connected to the second end surface of the vibrating component. The area of the first surface is greater than that of the second end surface. The spinning component generates a spinning motion centered on the central axis according to the vibration with the vibrating frequency generated by the vibrating component. Wherein, the spinning component transmits the vibration and the spinning motion to the cutting tool.

Provided are an ultrasound imaging apparatus and a surgical operation support system for obtaining position information of a device outside an imaging area and presenting the position information to a user together with an ultrasound image. The surgical operation support system includes the ultrasound imaging apparatus, an ultrasonic source fixed to a therapeutic tool to be inserted into a subject body, a display device for displaying the ultrasound image and the position of the ultrasonic source. The ultrasound imaging apparatus is provided with a position estimator for estimating the position information of the ultrasonic source, and the position estimator analyzes a grating lobe artifact (false image) that is generated by the ultrasonic wave emitted from the ultrasonic source outside the imaging area, to estimate the position information of the ultrasonic source with respect to the imaging area.

A tactile device includes: a substrate provided with a first surface; an organic piezoelectric film arranged on the first surface side; a plurality of electrodes arranged on the first surface; and a plurality of drive circuits arranged between the substrate and the organic piezoelectric film. The plurality of electrodes includes: a common electrode arranged across a plurality of cells; and a plurality of driving electrodes respectively arranged in the plurality of cells. The plurality of drive circuits includes: a first drive circuit capable of supplying a first driving signal; and a second drive circuit capable of supplying a second driving signal. The plurality of driving electrodes includes: a first driving electrode connected to the first drive circuit; and a second driving electrode connected to the second drive circuit. The first driving electrode and the second driving electrode are arranged in each of the plurality of cells.

Substrate is produced by using a MEMS technique to form multiple diaphragms in a substrate by forming piezoelectric material layer on one surface of the substrate and thereafter by forming openings in the substrate from the other surface of the substrate; substrate and substrate on which signal detection circuit is formed are aligned to each other using at least one of multiple diaphragms as alignment diaphragm; and substrate and substrate are bonded together.

The ultrasonic diagnostic apparatus includes: a transducer; a driving signal generation unit configured to generate a driving signal; and a transmission circuit configured to output a driving current corresponding to the driving signal, so as to drive the transducer, the transmission circuit includes: a transducer driving unit formed by a current mirror with a low voltage transistor and a high voltage transistor, the high voltage transistor being connected with the transducer, and a current source configured to supply an operation current corresponding to the driving signal to the low voltage transistor of the transducer driving unit, the driving signal generation unit includes: a transmission circuit driving unit replica that has a configuration same as that of the transducer driving unit, and a feedback control unit to detect a current flowing through a high voltage transistor of the transmission circuit driving unit replica, and to control the current to be constant.