An ultrasound imaging system includes an intraluminal ultrasound device configured to be positioned within a body lumen of a patient. The intraluminal ultrasound device includes a transducer array disposed along a distal portion of a flexible elongate member. The transducer array includes an aperture and is configured to obtain imaging data along one or more imaging planes. The system also includes a processor in communication with the transducer array. The processor is configured to: receive first imaging data from the transducer array along a first imaging plane at a first angular position with respect to an axial direction of the aperture; output, to a display device in communication with the processor, the first imaging data; and output, to the display device, a visual representation of the first angular position of the first imaging plane with respect to the axial direction of the aperture.

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 ultrasonic diagnostic apparatus includes: a plurality of receiving elements that receive an ultrasonic wave, convert the ultrasonic wave into an electric signal, and output a receiving signal; a first detecting amplifier that detects noise and outputs a noise signal; a second detecting amplifier that amplifies the noise signal and outputs an amplified noise signal; a subtraction amplifier that receives the receiving signal and the amplified noise signal and subtracts the amplified noise signal from the receiving signal; and a plurality of circuit substrates that each include the second detecting amplifier and subtraction amplifier.

The invention relates to the field of ultrasonic imaging detection, and more particularly, to an ultrasonic system of a contact type flexible conformal ultrasonic probe and a method for the same. The ultrasonic system comprises: a flexible probe, comprising a flexible detection surface, a plurality of probe units, and a soft film sensing surface; a switch module; a control module, comprising: a transmitting control unit for sequentially controlling the probe units in the probe array to transmit the ultrasonic signal; a receiving control unit for sequentially controlling the probe units in the probe array to receive the ultrasonic signal, and for processing the ultrasonic signal to obtain a ultrasonic image. The present invention has the following beneficial effects: the use of a flexible probe for acquiring an ultrasonic image allows to solve the problem that the operation process and imaging steps are complicated when using a rigid probe.

The invention relates to a medical device having reduced susceptibility to EMI. The medical device includes a body, a first electrical conductor, a second electrical conductor, a first polarized transducer, and a second polarized transducer. The first electrical conductor and the second electrical conductor each extend along the body. The first polarized transducer and the second polarized transducer are attached to the body such that their outer faces have opposite polarity. Moreover, the first polarized transducer and the second polarized transducer are connected between the first electrical conductor and second electrical conductor either i) electrically in series and with the same polarity; or ii) electrically in parallel and with the same polarity.

An ultrasound system is disclosed comprising an ultrasound transducer array (100) comprising a plurality of ultrasound transducer cells (130), each of said cell having an independently adjustable position and/or orientation such as to conform an ultrasound transmitting surface of the cell to a region of a body and a controller (140). The controller is configured to register the respective ultrasound transducer cells by simultaneously operating at least two ultrasound transducer cells in a transmit mode in which the cells transmit distinguishable ultrasound signals and operating the remaining ultrasound transducer cells in a receive mode. The controller extracts time-of-flight information of the respective ultrasound signals between transmitter and receiver and by systematically selecting different ultrasound transducer cells as transmitters, the controller collects sufficient time-of-flight information from which the respective position and/or relative orientation of the ultrasound transducer cells within the ultrasound transducer array may be derived. A method for operating the ultrasound system in this manner as well as a computer program product is also disclosed.

A transceiver includes an array of pMUT elements, where each pMUT element includes: a substrate; a membrane suspending from the substrate; a bottom electrode disposed on the membrane; a piezoelectric layer disposed on the bottom electrode; and a first electrode disposed on the piezoelectric layer. Each pMUT element exhibits one or more modes of vibration.

The present disclosure includes ultrasound systems and methods for imaging anisotropic tissue with shear wave elastography at a variety of angles with respect to the tissue. An example ultrasound imaging system includes a probe coupled to a position tracking system for tracking a position of the probe with respect to a subject, and a processor in communication with the probe. The processor may receive position tracking data from the position tracking system. The processor may define at least one target plane in anisotropic tissue, determine a difference between a current position of the probe and the position of the target plane, and provide a visual indicator of the difference, wherein the processor dynamically updates the visual indicator responsive to a change in the position of the imaging plane with respect to the target plane.

Disclosed herein are systems and methods for visualizing a target anatomy of a patient in preparation of a medical procedure. A system can have transducers defining a grid to collect data about the target anatomy. A user interface (22014) can be disposed on area of the system to visualize the target anatomy. The visualization can include a virtual representation (22016) formed by an imager processor based on the data collected by the transducers. The method can include positioning the visualization device at an orientation where the transducers face the target anatomy. The method can further include adjusting the position of the visualization device to a target anatomy displayed on the virtual representation. The method can further include directing a medical instrument towards a target displayed on the virtual representation.

Described herein are methods and apparatuses for packaging an ultrasound-on-a-chip. An ultrasound-on-a-chip may be coupled to a redistribution layer and to an interposer layer. Encapsulation may encapsulate the ultrasound-on-a-chip device and first metal pillars may extend through the encapsulation and electrically couple to the redistribution layer. Second metal pillars may extend through the interposer layer. The interposer layer may include aluminum nitride. The first metal pillars may be electrically coupled to the second metal pillars. A printed circuit board may be coupled to the interposer layer.