An ultrasound transducer unit including a plurality of ultrasound transducers transmits and receives ultrasound waves to and from an inside of a subject. In a case where a checking operation unit is operated, a controller controls a driving voltage supply unit such that a driving voltage is supplied with all of the plurality of ultrasound transducers as driving target transducers. In a case where the checking operation unit is operated, a depolarization determination unit calculates, for each ultrasound transducer, a reception sensitivity in a case where an ultrasound wave is received by driving all of the plurality of ultrasound transducers as the driving target transducers, and determines whether or not a depolarization determination value calculated from the reception sensitivity of each ultrasound transducer satisfies numerical conditions. If the numerical conditions are satisfied, a polarization voltage supply unit supplies a polarization voltage to each of the plurality of ultrasound transducers.

The invention relates to a method of optimizing a process for constructing ultrasound image data of a medium, wherein the method comprises: providing (a) ultrasound spatio-temporal signal data of the medium, determining (c) a specular property of the medium as a function of the signal data, optimizing (d) the process based on the specular property.

A control system for an ultrasound transmission/reception apparatus with a plurality of acoustic transducers for transmitting and receiving ultrasound signals may include driving device operatively coupled to the acoustic transducers and a control unit. The control unit may cyclically control the acoustic transducers in a transmission state for transmitting ultrasound signals, and in a reception state for receiving echoes of the transmitted ultrasound signals. The control unit may include an input stage which receives an external timing signal, and a processing stage which detects a first edge of the timing signal to determine the start time of a transmission phase during which the acoustic transducers are controlled in the transmission state, and a second edge of the timing signal to determine the stop time of a reception phase during which the acoustic transducers are controlled in the reception state.

An ultrasound-on-a-chip device has an ultrasonic transducer substrate with plurality of transducer cells, and an electrical substrate. For each transducer cell, one or more conductive bond connections are disposed between the ultrasonic transducer substrate and the electrical substrate. Examples of electrical substrates include CMOS chips, integrated circuits including analog circuits, interposers and printed circuit boards.

A pair of ophthalmic lens having an electronic system is described herein for communicating between them using ultrasound transducers for creating a sound pressure wave(s) to be scattered by the nose of the wearer of the ophthalmic lenses. The ophthalmic lenses include at least one ultrasound module having at least one transducer such as a pair of transmit and receive transducers, a transceiver transducer or a plurality of transducers. The ultrasound module includes additional components for the creation and reception of the sound pressure wave(s). In at least one embodiment, the sound pressure wave(s) encodes a message between the contact lenses. In at least one embodiment, the ophthalmic lenses include contact lenses or intraocular lenses.

Micromachined ultrasonic transducers having pressure ports are described. The micromachined ultrasonic transducers may comprise flexible membranes configured to vibrate over a cavity. The cavity may be sealed, in some instances by the membrane itself. A pressure port may provide access to the cavity, and thus control of the cavity pressure. In some embodiments, an ultrasound device including an array of micromachined ultrasonic transducers is provided, with pressure ports for at least some of the ultrasonic transducers. The pressure ports may be used to control pressure across the array.

An ultrasound-on-a-chip device has an ultrasonic transducer substrate with plurality of transducer cells, and an electrical substrate. For each transducer cell, one or more conductive bond connections are disposed between the ultrasonic transducer substrate and the electrical substrate. Examples of electrical substrates include CMOS chips, integrated circuits including analog circuits, interposers and printed circuit boards.

An electronic device including an array of ultrasonic transducers, a temperature sensor for determining a temperature of the array of ultrasonic transducers, and a control module communicatively coupled to the array of ultrasonic devices and the temperature sensor. The control module is for receiving the temperature and for controlling operation of the array of ultrasonic transducers based at least in part on the temperature.

A transducer array (802) includes at least one 1D array of transducing elements (804). The at least one 1D array of transducing elements includes a plurality of transducing elements (904). A first of the plurality of transducing elements has a first apodization and a second of the plurality of transducing elements has a second apodization. The first apodization and the second apodization are different. The transducer array further includes at least one electrically conductive element (910) in electrical communication with each of the plurality of transducing elements. The transducer array further includes at least one electrical contact (906) in electrical communication with the at least one electrically conductive element. The at least one electrical contact concurrently addresses the plurality of transducing elements through the at least one electrically conductive element.

An intraluminal imaging device is provided that includes a flexible elongate member (115) configured for positioning within a body lumen of a patient, a support member (300) coupled to the flexible elongate member, and an imaging assembly (110) coupled to the support member. The support member can include a proximal section (310) configured to interface with a distal portion of the flexible elongate member and a distal section (320) configured to interface with a proximal end of the imaging assembly, wherein the proximal section has a first diameter and the distal section has a second diameter less than the first diameter.